#include "ggml-rpc.h" #include "ggml-impl.h" #include "ggml-backend-impl.h" #include "ggml-cpp.h" #include #include #include #include #include #include #include #ifdef _WIN32 # define WIN32_LEAN_AND_MEAN # ifndef NOMINMAX # define NOMINMAX # endif # include # include #else # include # include # include # include # include # include # include #endif #include #include #include namespace fs = std::filesystem; #ifdef _WIN32 typedef SOCKET sockfd_t; using ssize_t = __int64; #else typedef int sockfd_t; #endif // cross-platform socket struct socket_t { sockfd_t fd; socket_t(sockfd_t fd) : fd(fd) {} ~socket_t() { GGML_PRINT_DEBUG("[%s] closing socket %d\n", __func__, this->fd); #ifdef _WIN32 closesocket(this->fd); #else close(this->fd); #endif } }; // all RPC structures must be packed #pragma pack(push, 1) // ggml_tensor is serialized into rpc_tensor struct rpc_tensor { uint64_t id; uint32_t type; uint64_t buffer; uint32_t ne[GGML_MAX_DIMS]; uint32_t nb[GGML_MAX_DIMS]; uint32_t op; int32_t op_params[GGML_MAX_OP_PARAMS / sizeof(int32_t)]; int32_t flags; uint64_t src[GGML_MAX_SRC]; uint64_t view_src; uint64_t view_offs; uint64_t data; char name[GGML_MAX_NAME]; char padding[4]; }; static_assert(sizeof(rpc_tensor) % 8 == 0, "rpc_tensor size must be multiple of 8"); // RPC commands enum rpc_cmd { RPC_CMD_ALLOC_BUFFER = 0, RPC_CMD_GET_ALIGNMENT, RPC_CMD_GET_MAX_SIZE, RPC_CMD_BUFFER_GET_BASE, RPC_CMD_FREE_BUFFER, RPC_CMD_BUFFER_CLEAR, RPC_CMD_SET_TENSOR, RPC_CMD_SET_TENSOR_HASH, RPC_CMD_GET_TENSOR, RPC_CMD_COPY_TENSOR, RPC_CMD_GRAPH_COMPUTE, RPC_CMD_GET_DEVICE_MEMORY, RPC_CMD_INIT_TENSOR, RPC_CMD_GET_ALLOC_SIZE, RPC_CMD_HELLO, RPC_CMD_COUNT, }; // Try RPC_CMD_SET_TENSOR_HASH first when data size is larger than this threshold const size_t HASH_THRESHOLD = 10 * 1024 * 1024; struct rpc_msg_hello_rsp { uint8_t major; uint8_t minor; uint8_t patch; }; struct rpc_msg_get_alloc_size_req { rpc_tensor tensor; }; struct rpc_msg_get_alloc_size_rsp { uint64_t alloc_size; }; struct rpc_msg_init_tensor_req { rpc_tensor tensor; }; struct rpc_msg_alloc_buffer_req { uint64_t size; }; struct rpc_msg_alloc_buffer_rsp { uint64_t remote_ptr; uint64_t remote_size; }; struct rpc_msg_get_alignment_rsp { uint64_t alignment; }; struct rpc_msg_get_max_size_rsp { uint64_t max_size; }; struct rpc_msg_buffer_get_base_req { uint64_t remote_ptr; }; struct rpc_msg_buffer_get_base_rsp { uint64_t base_ptr; }; struct rpc_msg_free_buffer_req { uint64_t remote_ptr; }; struct rpc_msg_buffer_clear_req { uint64_t remote_ptr; uint8_t value; }; struct rpc_msg_set_tensor_hash_req { rpc_tensor tensor; uint64_t offset; uint64_t hash; }; struct rpc_msg_set_tensor_hash_rsp { uint8_t result; }; struct rpc_msg_get_tensor_req { rpc_tensor tensor; uint64_t offset; uint64_t size; }; struct rpc_msg_copy_tensor_req { rpc_tensor src; rpc_tensor dst; }; struct rpc_msg_copy_tensor_rsp { uint8_t result; }; struct rpc_msg_graph_compute_rsp { uint8_t result; }; struct rpc_msg_get_device_memory_rsp { uint64_t free_mem; uint64_t total_mem; }; #pragma pack(pop) // RPC data structures static ggml_guid_t ggml_backend_rpc_guid() { static ggml_guid guid = {0x99, 0x68, 0x5b, 0x6c, 0xd2, 0x83, 0x3d, 0x24, 0x25, 0x36, 0x72, 0xe1, 0x5b, 0x0e, 0x14, 0x03}; return &guid; } struct ggml_backend_rpc_buffer_type_context { std::string endpoint; std::string name; size_t alignment; size_t max_size; }; struct ggml_backend_rpc_context { std::string endpoint; std::string name; }; struct ggml_backend_rpc_buffer_context { std::shared_ptr sock; void * base_ptr; uint64_t remote_ptr; }; // RPC helper functions // Computes FNV-1a hash of the data static uint64_t fnv_hash(const uint8_t * data, size_t len) { const uint64_t fnv_prime = 0x100000001b3ULL; uint64_t hash = 0xcbf29ce484222325ULL; for (size_t i = 0; i < len; ++i) { hash ^= data[i]; hash *= fnv_prime; } return hash; } static std::shared_ptr make_socket(sockfd_t fd) { #ifdef _WIN32 if (fd == INVALID_SOCKET) { return nullptr; } #else if (fd < 0) { return nullptr; } #endif return std::make_shared(fd); } static bool set_no_delay(sockfd_t sockfd) { int flag = 1; // set TCP_NODELAY to disable Nagle's algorithm int ret = setsockopt(sockfd, IPPROTO_TCP, TCP_NODELAY, (char *)&flag, sizeof(int)); return ret == 0; } static bool set_reuse_addr(sockfd_t sockfd) { int flag = 1; int ret = setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, (char *)&flag, sizeof(int)); return ret == 0; } static std::shared_ptr socket_connect(const char * host, int port) { struct sockaddr_in addr; auto sockfd = socket(AF_INET, SOCK_STREAM, 0); auto sock_ptr = make_socket(sockfd); if (sock_ptr == nullptr) { return nullptr; } if (!set_no_delay(sockfd)) { fprintf(stderr, "Failed to set TCP_NODELAY\n"); return nullptr; } addr.sin_family = AF_INET; addr.sin_port = htons(port); struct hostent * server = gethostbyname(host); if (server == NULL) { fprintf(stderr, "Cannot resolve host '%s'\n", host); return nullptr; } memcpy(&addr.sin_addr.s_addr, server->h_addr, server->h_length); if (connect(sock_ptr->fd, (struct sockaddr *)&addr, sizeof(addr)) < 0) { return nullptr; } return sock_ptr; } static std::shared_ptr socket_accept(sockfd_t srv_sockfd) { auto client_socket_fd = accept(srv_sockfd, NULL, NULL); auto client_socket = make_socket(client_socket_fd); if (client_socket == nullptr) { return nullptr; } if (!set_no_delay(client_socket_fd)) { fprintf(stderr, "Failed to set TCP_NODELAY\n"); return nullptr; } return client_socket; } static std::shared_ptr create_server_socket(const char * host, int port) { auto sockfd = socket(AF_INET, SOCK_STREAM, 0); auto sock = make_socket(sockfd); if (sock == nullptr) { return nullptr; } if (!set_reuse_addr(sockfd)) { fprintf(stderr, "Failed to set SO_REUSEADDR\n"); return nullptr; } if (inet_addr(host) == INADDR_NONE) { fprintf(stderr, "Invalid host address: %s\n", host); return nullptr; } struct sockaddr_in serv_addr; serv_addr.sin_family = AF_INET; serv_addr.sin_addr.s_addr = inet_addr(host); serv_addr.sin_port = htons(port); if (bind(sockfd, (struct sockaddr *) &serv_addr, sizeof(serv_addr)) < 0) { return nullptr; } if (listen(sockfd, 1) < 0) { return nullptr; } return sock; } static bool send_data(sockfd_t sockfd, const void * data, size_t size) { size_t bytes_sent = 0; while (bytes_sent < size) { ssize_t n = send(sockfd, (const char *)data + bytes_sent, size - bytes_sent, 0); if (n < 0) { return false; } bytes_sent += n; } return true; } static bool recv_data(sockfd_t sockfd, void * data, size_t size) { size_t bytes_recv = 0; while (bytes_recv < size) { ssize_t n = recv(sockfd, (char *)data + bytes_recv, size - bytes_recv, 0); if (n <= 0) { return false; } bytes_recv += n; } return true; } static bool send_msg(sockfd_t sockfd, const void * msg, size_t msg_size) { if (!send_data(sockfd, &msg_size, sizeof(msg_size))) { return false; } return send_data(sockfd, msg, msg_size); } static bool recv_msg(sockfd_t sockfd, void * msg, size_t msg_size) { uint64_t size; if (!recv_data(sockfd, &size, sizeof(size))) { return false; } if (size != msg_size) { return false; } return recv_data(sockfd, msg, msg_size); } static bool recv_msg(sockfd_t sockfd, std::vector & input) { uint64_t size; if (!recv_data(sockfd, &size, sizeof(size))) { return false; } try { input.resize(size); } catch (const std::bad_alloc & e) { fprintf(stderr, "Failed to allocate input buffer of size %" PRIu64 "\n", size); return false; } return recv_data(sockfd, input.data(), size); } static bool parse_endpoint(const std::string & endpoint, std::string & host, int & port) { size_t pos = endpoint.find(':'); if (pos == std::string::npos) { return false; } host = endpoint.substr(0, pos); port = std::stoi(endpoint.substr(pos + 1)); return true; } // RPC request : | rpc_cmd (1 byte) | request_size (8 bytes) | request_data (request_size bytes) | // No response static bool send_rpc_cmd(const std::shared_ptr & sock, enum rpc_cmd cmd, const void * input, size_t input_size) { uint8_t cmd_byte = cmd; if (!send_data(sock->fd, &cmd_byte, sizeof(cmd_byte))) { return false; } if (!send_data(sock->fd, &input_size, sizeof(input_size))) { return false; } if (!send_data(sock->fd, input, input_size)) { return false; } return true; } // RPC request : | rpc_cmd (1 byte) | request_size (8 bytes) | request_data (request_size bytes) | // RPC response: | response_size (8 bytes) | response_data (response_size bytes) | static bool send_rpc_cmd(const std::shared_ptr & sock, enum rpc_cmd cmd, const void * input, size_t input_size, void * output, size_t output_size) { if (!send_rpc_cmd(sock, cmd, input, input_size)) { return false; } // TODO: currently the output_size is always known, do we need support for commands with variable output size? // even if we do, we can skip sending output_size from the server for commands with known output size uint64_t out_size; if (!recv_data(sock->fd, &out_size, sizeof(out_size))) { return false; } if (out_size != output_size) { return false; } if (!recv_data(sock->fd, output, output_size)) { return false; } return true; } // RPC client-side implementation static bool check_server_version(const std::shared_ptr & sock) { rpc_msg_hello_rsp response; bool status = send_rpc_cmd(sock, RPC_CMD_HELLO, nullptr, 0, &response, sizeof(response)); GGML_ASSERT(status); if (response.major != RPC_PROTO_MAJOR_VERSION || response.minor > RPC_PROTO_MINOR_VERSION) { fprintf(stderr, "RPC server version mismatch: %d.%d.%d\n", response.major, response.minor, response.patch); return false; } if (response.minor != RPC_PROTO_MINOR_VERSION || response.patch != RPC_PROTO_PATCH_VERSION) { fprintf(stderr, "WARNING: RPC server version mismatch: %d.%d.%d\n", response.major, response.minor, response.patch); } return true; } static std::shared_ptr get_socket(const std::string & endpoint) { static std::mutex mutex; std::lock_guard lock(mutex); static std::unordered_map> sockets; static bool initialized = false; auto it = sockets.find(endpoint); if (it != sockets.end()) { if (auto sock = it->second.lock()) { return sock; } } std::string host; int port; if (!parse_endpoint(endpoint, host, port)) { return nullptr; } #ifdef _WIN32 if (!initialized) { WSADATA wsaData; int res = WSAStartup(MAKEWORD(2, 2), &wsaData); if (res != 0) { return nullptr; } initialized = true; } #else GGML_UNUSED(initialized); #endif auto sock = socket_connect(host.c_str(), port); if (sock == nullptr) { return nullptr; } if (!check_server_version(sock)) { return nullptr; } GGML_PRINT_DEBUG("[%s] connected to %s, sockfd=%d\n", __func__, endpoint.c_str(), sock->fd); sockets[endpoint] = sock; return sock; } static void ggml_backend_rpc_buffer_free_buffer(ggml_backend_buffer_t buffer) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; rpc_msg_free_buffer_req request = {ctx->remote_ptr}; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_FREE_BUFFER, &request, sizeof(request), nullptr, 0); GGML_ASSERT(status); delete ctx; } static void * ggml_backend_rpc_buffer_get_base(ggml_backend_buffer_t buffer) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; if (ctx->base_ptr != nullptr) { return ctx->base_ptr; } rpc_msg_buffer_get_base_req request = {ctx->remote_ptr}; rpc_msg_buffer_get_base_rsp response; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_BUFFER_GET_BASE, &request, sizeof(request), &response, sizeof(response)); GGML_ASSERT(status); ctx->base_ptr = reinterpret_cast(response.base_ptr); return ctx->base_ptr; } static rpc_tensor serialize_tensor(const ggml_tensor * tensor) { rpc_tensor result; result.id = reinterpret_cast(tensor); result.type = tensor->type; if (tensor->buffer) { ggml_backend_buffer_t buffer = tensor->buffer; ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; result.buffer = ctx->remote_ptr; } else { result.buffer = 0; } for (uint32_t i = 0; i < GGML_MAX_DIMS; i++) { result.ne[i] = tensor->ne[i]; result.nb[i] = tensor->nb[i]; } result.op = tensor->op; for (uint32_t i = 0; i < GGML_MAX_OP_PARAMS / sizeof(int32_t); i++) { result.op_params[i] = tensor->op_params[i]; } result.flags = tensor->flags; for (uint32_t i = 0; i < GGML_MAX_SRC; i++) { result.src[i] = reinterpret_cast(tensor->src[i]); } result.view_src = reinterpret_cast(tensor->view_src); result.view_offs = tensor->view_offs; result.data = reinterpret_cast(tensor->data); // Avoid sending uninitialized data over the wire memset(result.name, 0, sizeof(result.name)); memset(result.padding, 0, sizeof(result.padding)); snprintf(result.name, GGML_MAX_NAME, "%s", tensor->name); return result; } static enum ggml_status ggml_backend_rpc_buffer_init_tensor(ggml_backend_buffer_t buffer, ggml_tensor * tensor) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; // CUDA backend on the server pads everything to 512 due to CUDA limitations. // Due to bandwidth constraints, we only call the server init tensor functions if necessary. // In particular, only quantized tensors need padding if (ggml_is_quantized(tensor->type) && (tensor->ne[0] % 512 != 0) && (tensor->view_src == nullptr)) { rpc_msg_init_tensor_req request; request.tensor = serialize_tensor(tensor); bool status = send_rpc_cmd(ctx->sock, RPC_CMD_INIT_TENSOR, &request, sizeof(request), nullptr, 0); GGML_ASSERT(status); } return GGML_STATUS_SUCCESS; } static void ggml_backend_rpc_buffer_set_tensor(ggml_backend_buffer_t buffer, ggml_tensor * tensor, const void * data, size_t offset, size_t size) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; rpc_tensor rpc_tensor = serialize_tensor(tensor); if (size > HASH_THRESHOLD) { rpc_msg_set_tensor_hash_req request; request.tensor = rpc_tensor; request.offset = offset; request.hash = fnv_hash((const uint8_t*)data, size); rpc_msg_set_tensor_hash_rsp response; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_SET_TENSOR_HASH, &request, sizeof(request), &response, sizeof(response)); GGML_ASSERT(status); if (response.result) { // the server has the same data, no need to send it return; } } // input serialization format: | rpc_tensor | offset (8 bytes) | data (size bytes) size_t input_size = sizeof(rpc_tensor) + sizeof(uint64_t) + size; std::vector input(input_size, 0); memcpy(input.data(), &rpc_tensor, sizeof(rpc_tensor)); memcpy(input.data() + sizeof(rpc_tensor), &offset, sizeof(offset)); memcpy(input.data() + sizeof(rpc_tensor) + sizeof(offset), data, size); bool status = send_rpc_cmd(ctx->sock, RPC_CMD_SET_TENSOR, input.data(), input.size()); GGML_ASSERT(status); } static void ggml_backend_rpc_buffer_get_tensor(ggml_backend_buffer_t buffer, const ggml_tensor * tensor, void * data, size_t offset, size_t size) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; rpc_msg_get_tensor_req request; request.tensor = serialize_tensor(tensor); request.offset = offset; request.size = size; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_GET_TENSOR, &request, sizeof(request), data, size); GGML_ASSERT(status); } static bool ggml_backend_rpc_buffer_cpy_tensor(ggml_backend_buffer_t buffer, const ggml_tensor * src, ggml_tensor * dst) { // check if src and dst are on the same server ggml_backend_buffer_t src_buffer = src->buffer; ggml_backend_rpc_buffer_context * src_ctx = (ggml_backend_rpc_buffer_context *)src_buffer->context; ggml_backend_buffer_t dst_buffer = dst->buffer; ggml_backend_rpc_buffer_context * dst_ctx = (ggml_backend_rpc_buffer_context *)dst_buffer->context; if (src_ctx->sock != dst_ctx->sock) { return false; } ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; rpc_msg_copy_tensor_req request; request.src = serialize_tensor(src); request.dst = serialize_tensor(dst); rpc_msg_copy_tensor_rsp response; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_COPY_TENSOR, &request, sizeof(request), &response, sizeof(response)); GGML_ASSERT(status); return response.result; } static void ggml_backend_rpc_buffer_clear(ggml_backend_buffer_t buffer, uint8_t value) { ggml_backend_rpc_buffer_context * ctx = (ggml_backend_rpc_buffer_context *)buffer->context; rpc_msg_buffer_clear_req request = {ctx->remote_ptr, value}; bool status = send_rpc_cmd(ctx->sock, RPC_CMD_BUFFER_CLEAR, &request, sizeof(request), nullptr, 0); GGML_ASSERT(status); } static ggml_backend_buffer_i ggml_backend_rpc_buffer_interface = { /* .free_buffer = */ ggml_backend_rpc_buffer_free_buffer, /* .get_base = */ ggml_backend_rpc_buffer_get_base, /* .init_tensor = */ ggml_backend_rpc_buffer_init_tensor, /* .memset_tensor = */ NULL, /* .set_tensor = */ ggml_backend_rpc_buffer_set_tensor, /* .get_tensor = */ ggml_backend_rpc_buffer_get_tensor, /* .cpy_tensor = */ ggml_backend_rpc_buffer_cpy_tensor, /* .clear = */ ggml_backend_rpc_buffer_clear, /* .reset = */ NULL, }; static const char * ggml_backend_rpc_buffer_type_name(ggml_backend_buffer_type_t buft) { ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; return buft_ctx->name.c_str(); } static ggml_backend_buffer_t ggml_backend_rpc_buffer_type_alloc_buffer(ggml_backend_buffer_type_t buft, size_t size) { ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; rpc_msg_alloc_buffer_req request = {size}; rpc_msg_alloc_buffer_rsp response; auto sock = get_socket(buft_ctx->endpoint); bool status = send_rpc_cmd(sock, RPC_CMD_ALLOC_BUFFER, &request, sizeof(request), &response, sizeof(response)); GGML_ASSERT(status); if (response.remote_ptr != 0) { ggml_backend_buffer_t buffer = ggml_backend_buffer_init(buft, ggml_backend_rpc_buffer_interface, new ggml_backend_rpc_buffer_context{sock, nullptr, response.remote_ptr}, response.remote_size); return buffer; } else { return nullptr; } } static size_t get_alignment(const std::shared_ptr & sock) { rpc_msg_get_alignment_rsp response; bool status = send_rpc_cmd(sock, RPC_CMD_GET_ALIGNMENT, nullptr, 0, &response, sizeof(response)); GGML_ASSERT(status); return response.alignment; } static size_t ggml_backend_rpc_buffer_type_get_alignment(ggml_backend_buffer_type_t buft) { ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; return buft_ctx->alignment; } static size_t get_max_size(const std::shared_ptr & sock) { rpc_msg_get_max_size_rsp response; bool status = send_rpc_cmd(sock, RPC_CMD_GET_MAX_SIZE, nullptr, 0, &response, sizeof(response)); GGML_ASSERT(status); return response.max_size; } static size_t ggml_backend_rpc_get_max_size(ggml_backend_buffer_type_t buft) { ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; return buft_ctx->max_size; } static size_t ggml_backend_rpc_buffer_type_get_alloc_size(ggml_backend_buffer_type_t buft, const ggml_tensor * tensor) { // See comments in init_tensor. if (ggml_is_quantized(tensor->type) && (tensor->ne[0] % 512 != 0) && (tensor->view_src == nullptr)) { ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; auto sock = get_socket(buft_ctx->endpoint); rpc_msg_get_alloc_size_req request; request.tensor = serialize_tensor(tensor); rpc_msg_get_alloc_size_rsp response; bool status = send_rpc_cmd(sock, RPC_CMD_GET_ALLOC_SIZE, &request, sizeof(request), &response, sizeof(response)); GGML_ASSERT(status); return response.alloc_size; } else { return ggml_nbytes(tensor); } } static ggml_backend_buffer_type_i ggml_backend_rpc_buffer_type_interface = { /* .get_name = */ ggml_backend_rpc_buffer_type_name, /* .alloc_buffer = */ ggml_backend_rpc_buffer_type_alloc_buffer, /* .get_alignment = */ ggml_backend_rpc_buffer_type_get_alignment, /* .get_max_size = */ ggml_backend_rpc_get_max_size, /* .get_alloc_size = */ ggml_backend_rpc_buffer_type_get_alloc_size, /* .is_host = */ NULL, }; static const char * ggml_backend_rpc_name(ggml_backend_t backend) { ggml_backend_rpc_context * rpc_ctx = (ggml_backend_rpc_context *)backend->context; return rpc_ctx->name.c_str(); } static void ggml_backend_rpc_free(ggml_backend_t backend) { ggml_backend_rpc_context * rpc_ctx = (ggml_backend_rpc_context *)backend->context; delete rpc_ctx; delete backend; } static void ggml_backend_rpc_synchronize(ggml_backend_t backend) { GGML_UNUSED(backend); // this is no-op because we don't have any async operations } static void add_tensor(ggml_tensor * tensor, std::vector & tensors, std::unordered_set & visited) { if (tensor == nullptr) { return; } if (visited.find(tensor) != visited.end()) { return; } visited.insert(tensor); for (int i = 0; i < GGML_MAX_SRC; i++) { add_tensor(tensor->src[i], tensors, visited); } add_tensor(tensor->view_src, tensors, visited); tensors.push_back(serialize_tensor(tensor)); } static void serialize_graph(const ggml_cgraph * cgraph, std::vector & output) { uint32_t n_nodes = cgraph->n_nodes; std::vector tensors; std::unordered_set visited; for (uint32_t i = 0; i < n_nodes; i++) { add_tensor(cgraph->nodes[i], tensors, visited); } // serialization format: // | n_nodes (4 bytes) | nodes (n_nodes * sizeof(uint64_t) | n_tensors (4 bytes) | tensors (n_tensors * sizeof(rpc_tensor)) | uint32_t n_tensors = tensors.size(); int output_size = sizeof(uint32_t) + n_nodes * sizeof(uint64_t) + sizeof(uint32_t) + n_tensors * sizeof(rpc_tensor); output.resize(output_size, 0); memcpy(output.data(), &n_nodes, sizeof(n_nodes)); for (uint32_t i = 0; i < n_nodes; i++) { memcpy(output.data() + sizeof(n_nodes) + i * sizeof(uint64_t), &cgraph->nodes[i], sizeof(uint64_t)); } uint32_t * out_ntensors = (uint32_t *)(output.data() + sizeof(n_nodes) + n_nodes * sizeof(uint64_t)); *out_ntensors = n_tensors; rpc_tensor * out_tensors = (rpc_tensor *)(output.data() + sizeof(n_nodes) + n_nodes * sizeof(uint64_t) + sizeof(uint32_t)); memcpy(out_tensors, tensors.data(), n_tensors * sizeof(rpc_tensor)); } static enum ggml_status ggml_backend_rpc_graph_compute(ggml_backend_t backend, ggml_cgraph * cgraph) { ggml_backend_rpc_context * rpc_ctx = (ggml_backend_rpc_context *)backend->context; std::vector input; serialize_graph(cgraph, input); rpc_msg_graph_compute_rsp response; auto sock = get_socket(rpc_ctx->endpoint); bool status = send_rpc_cmd(sock, RPC_CMD_GRAPH_COMPUTE, input.data(), input.size(), &response, sizeof(response)); GGML_ASSERT(status); return (enum ggml_status)response.result; } static ggml_backend_i ggml_backend_rpc_interface = { /* .get_name = */ ggml_backend_rpc_name, /* .free = */ ggml_backend_rpc_free, /* .set_tensor_async = */ NULL, /* .get_tensor_async = */ NULL, /* .cpy_tensor_async = */ NULL, /* .synchronize = */ ggml_backend_rpc_synchronize, /* .graph_plan_create = */ NULL, /* .graph_plan_free = */ NULL, /* .graph_plan_update = */ NULL, /* .graph_plan_compute = */ NULL, /* .graph_compute = */ ggml_backend_rpc_graph_compute, /* .event_record = */ NULL, /* .event_wait = */ NULL, }; ggml_backend_buffer_type_t ggml_backend_rpc_buffer_type(const char * endpoint) { static std::mutex mutex; std::lock_guard lock(mutex); // NOTE: buffer types are allocated and never freed; this is by design static std::unordered_map buft_map; auto it = buft_map.find(endpoint); if (it != buft_map.end()) { return it->second; } auto sock = get_socket(endpoint); if (sock == nullptr) { fprintf(stderr, "Failed to connect to %s\n", endpoint); return nullptr; } size_t alignment = get_alignment(sock); size_t max_size = get_max_size(sock); ggml_backend_rpc_buffer_type_context * buft_ctx = new ggml_backend_rpc_buffer_type_context { /* .endpoint = */ endpoint, /* .name = */ "RPC[" + std::string(endpoint) + "]", /* .alignment = */ alignment, /* .max_size = */ max_size }; ggml_backend_buffer_type_t buft = new ggml_backend_buffer_type { /* .iface = */ ggml_backend_rpc_buffer_type_interface, /* .device = */ ggml_backend_rpc_add_device(endpoint), /* .context = */ buft_ctx }; buft_map[endpoint] = buft; return buft; } ggml_backend_t ggml_backend_rpc_init(const char * endpoint) { ggml_backend_rpc_context * ctx = new ggml_backend_rpc_context { /* .endpoint = */ endpoint, /* .name = */ "RPC[" + std::string(endpoint) + "]", }; ggml_backend_t backend = new ggml_backend { /* .guid = */ ggml_backend_rpc_guid(), /* .interface = */ ggml_backend_rpc_interface, /* .device = */ ggml_backend_rpc_add_device(endpoint), /* .context = */ ctx }; return backend; } bool ggml_backend_is_rpc(ggml_backend_t backend) { return backend != NULL && ggml_guid_matches(backend->guid, ggml_backend_rpc_guid()); } static void get_device_memory(const std::shared_ptr & sock, size_t * free, size_t * total) { rpc_msg_get_device_memory_rsp response; bool status = send_rpc_cmd(sock, RPC_CMD_GET_DEVICE_MEMORY, nullptr, 0, &response, sizeof(response)); GGML_ASSERT(status); *free = response.free_mem; *total = response.total_mem; } void ggml_backend_rpc_get_device_memory(const char * endpoint, size_t * free, size_t * total) { auto sock = get_socket(endpoint); if (sock == nullptr) { *free = 0; *total = 0; return; } get_device_memory(sock, free, total); } // RPC server-side implementation class rpc_server { public: rpc_server(ggml_backend_t backend, const char * cache_dir) : backend(backend), cache_dir(cache_dir) { } ~rpc_server(); void hello(rpc_msg_hello_rsp & response); void alloc_buffer(const rpc_msg_alloc_buffer_req & request, rpc_msg_alloc_buffer_rsp & response); void get_alignment(rpc_msg_get_alignment_rsp & response); void get_max_size(rpc_msg_get_max_size_rsp & response); bool buffer_get_base(const rpc_msg_buffer_get_base_req & request, rpc_msg_buffer_get_base_rsp & response); bool free_buffer(const rpc_msg_free_buffer_req & request); bool buffer_clear(const rpc_msg_buffer_clear_req & request); bool set_tensor(const std::vector & input); bool set_tensor_hash(const rpc_msg_set_tensor_hash_req & request, rpc_msg_set_tensor_hash_rsp & response); bool get_tensor(const rpc_msg_get_tensor_req & request, std::vector & response); bool copy_tensor(const rpc_msg_copy_tensor_req & request, rpc_msg_copy_tensor_rsp & response); bool graph_compute(const std::vector & input, rpc_msg_graph_compute_rsp & response); bool init_tensor(const rpc_msg_init_tensor_req & request); bool get_alloc_size(const rpc_msg_get_alloc_size_req & request, rpc_msg_get_alloc_size_rsp & response); private: bool get_cached_file(uint64_t hash, std::vector & data); ggml_tensor * deserialize_tensor(struct ggml_context * ctx, const rpc_tensor * tensor); ggml_tensor * create_node(uint64_t id, struct ggml_context * ctx, const std::unordered_map & tensor_ptrs, std::unordered_map & tensor_map); ggml_backend_t backend; const char * cache_dir; std::unordered_set buffers; }; void rpc_server::hello(rpc_msg_hello_rsp & response) { response.major = RPC_PROTO_MAJOR_VERSION; response.minor = RPC_PROTO_MINOR_VERSION; response.patch = RPC_PROTO_PATCH_VERSION; GGML_PRINT_DEBUG("[%s] version: %d.%d.%d\n", __func__, response.major, response.minor, response.patch); } bool rpc_server::get_alloc_size(const rpc_msg_get_alloc_size_req & request, rpc_msg_get_alloc_size_rsp & response) { ggml_backend_buffer_type_t buft; struct ggml_init_params params { /*.mem_size =*/ ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * tensor = deserialize_tensor(ctx, &request.tensor); if (tensor == nullptr) { GGML_LOG_ERROR("Null tensor pointer passed to server get_alloc_size function.\n"); return false; } if (tensor->buffer == nullptr) { //No buffer allocated. buft = ggml_backend_get_default_buffer_type(backend); } else { buft = tensor->buffer->buft; } response.alloc_size = ggml_backend_buft_get_alloc_size(buft,tensor); return true; } void rpc_server::alloc_buffer(const rpc_msg_alloc_buffer_req & request, rpc_msg_alloc_buffer_rsp & response) { ggml_backend_buffer_type_t buft = ggml_backend_get_default_buffer_type(backend); ggml_backend_buffer_t buffer = ggml_backend_buft_alloc_buffer(buft, request.size); response.remote_ptr = 0; response.remote_size = 0; if (buffer != nullptr) { response.remote_ptr = reinterpret_cast(buffer); response.remote_size = buffer->size; GGML_PRINT_DEBUG("[%s] size: %" PRIu64 " -> remote_ptr: %" PRIx64 ", remote_size: %" PRIu64 "\n", __func__, request.size, response.remote_ptr, response.remote_size); buffers.insert(buffer); } else { GGML_LOG_ERROR("[%s] size: %" PRIu64 " -> failed\n", __func__, request.size); } } void rpc_server::get_alignment(rpc_msg_get_alignment_rsp & response) { ggml_backend_buffer_type_t buft = ggml_backend_get_default_buffer_type(backend); size_t alignment = ggml_backend_buft_get_alignment(buft); GGML_PRINT_DEBUG("[%s] alignment: %lu\n", __func__, alignment); response.alignment = alignment; } void rpc_server::get_max_size(rpc_msg_get_max_size_rsp & response) { ggml_backend_buffer_type_t buft = ggml_backend_get_default_buffer_type(backend); size_t max_size = ggml_backend_buft_get_max_size(buft); GGML_PRINT_DEBUG("[%s] max_size: %lu\n", __func__, max_size); response.max_size = max_size; } bool rpc_server::buffer_get_base(const rpc_msg_buffer_get_base_req & request, rpc_msg_buffer_get_base_rsp & response) { GGML_PRINT_DEBUG("[%s] remote_ptr: %" PRIx64 "\n", __func__, request.remote_ptr); ggml_backend_buffer_t buffer = reinterpret_cast(request.remote_ptr); if (buffers.find(buffer) == buffers.end()) { GGML_LOG_ERROR("[%s] buffer not found\n", __func__); return false; } void * base = ggml_backend_buffer_get_base(buffer); response.base_ptr = reinterpret_cast(base); return true; } bool rpc_server::free_buffer(const rpc_msg_free_buffer_req & request) { GGML_PRINT_DEBUG("[%s] remote_ptr: %" PRIx64 "\n", __func__, request.remote_ptr); ggml_backend_buffer_t buffer = reinterpret_cast(request.remote_ptr); if (buffers.find(buffer) == buffers.end()) { GGML_LOG_ERROR("[%s] buffer not found\n", __func__); return false; } ggml_backend_buffer_free(buffer); buffers.erase(buffer); return true; } bool rpc_server::buffer_clear(const rpc_msg_buffer_clear_req & request) { GGML_PRINT_DEBUG("[%s] remote_ptr: %" PRIx64 ", value: %u\n", __func__, request.remote_ptr, request.value); ggml_backend_buffer_t buffer = reinterpret_cast(request.remote_ptr); if (buffers.find(buffer) == buffers.end()) { GGML_LOG_ERROR("[%s] buffer not found\n", __func__); return false; } ggml_backend_buffer_clear(buffer, request.value); return true; } ggml_tensor * rpc_server::deserialize_tensor(struct ggml_context * ctx, const rpc_tensor * tensor) { // Validate tensor type before using it if (tensor->type >= GGML_TYPE_COUNT) { GGML_LOG_ERROR("[%s] invalid tensor type received: %u\n", __func__, tensor->type); return nullptr; } ggml_tensor * result = ggml_new_tensor_4d(ctx, (ggml_type) tensor->type, tensor->ne[0], tensor->ne[1], tensor->ne[2], tensor->ne[3]); // ggml_new_tensor_4d might fail if dimensions are invalid, although less likely to crash than invalid type if (result == nullptr) { GGML_LOG_ERROR("[%s] ggml_new_tensor_4d failed for type %u\\n", __func__, tensor->type); return nullptr; } for (uint32_t i = 0; i < GGML_MAX_DIMS; i++) { result->nb[i] = tensor->nb[i]; } result->buffer = reinterpret_cast(tensor->buffer); if (result->buffer && buffers.find(result->buffer) == buffers.end()) { result->buffer = nullptr; } if (result->buffer) { // require that the tensor data does not go beyond the buffer end uint64_t tensor_size = (uint64_t) ggml_nbytes(result); uint64_t buffer_start = (uint64_t) ggml_backend_buffer_get_base(result->buffer); uint64_t buffer_size = (uint64_t) ggml_backend_buffer_get_size(result->buffer); GGML_ASSERT(tensor->data + tensor_size >= tensor->data); // check for overflow GGML_ASSERT(tensor->data >= buffer_start && tensor->data + tensor_size <= buffer_start + buffer_size); } result->op = (ggml_op) tensor->op; for (uint32_t i = 0; i < GGML_MAX_OP_PARAMS / sizeof(int32_t); i++) { result->op_params[i] = tensor->op_params[i]; } result->flags = tensor->flags; result->data = reinterpret_cast(tensor->data); ggml_set_name(result, tensor->name); return result; } bool rpc_server::set_tensor(const std::vector & input) { // serialization format: | rpc_tensor | offset (8 bytes) | data (size bytes) | if (input.size() < sizeof(rpc_tensor) + sizeof(uint64_t)) { return false; } const rpc_tensor * in_tensor = (const rpc_tensor *)input.data(); uint64_t offset; memcpy(&offset, input.data() + sizeof(rpc_tensor), sizeof(offset)); const size_t size = input.size() - sizeof(rpc_tensor) - sizeof(offset); struct ggml_init_params params { /*.mem_size =*/ ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * tensor = deserialize_tensor(ctx, in_tensor); if (tensor == nullptr) { GGML_LOG_ERROR("[%s] error deserializing tensor\n", __func__); return false; } GGML_PRINT_DEBUG("[%s] buffer: %p, data: %p, offset: %" PRIu64 ", size: %zu\n", __func__, (void*)tensor->buffer, tensor->data, offset, size); // sanitize tensor->data { const size_t p0 = (size_t) ggml_backend_buffer_get_base(tensor->buffer); const size_t p1 = p0 + ggml_backend_buffer_get_size(tensor->buffer); if (in_tensor->data + offset < p0 || in_tensor->data + offset >= p1 || size > (p1 - in_tensor->data - offset)) { GGML_LOG_ERROR("[%s] tensor data region (data=0x%" PRIx64 ", offset=%" PRIu64 ", size=%zu) out of buffer bounds [0x%zx, 0x%zx)\n", __func__, in_tensor->data, offset, size, p0, p1); return false; } } const void * data = input.data() + sizeof(rpc_tensor) + sizeof(offset); if (cache_dir && size > HASH_THRESHOLD) { uint64_t hash = fnv_hash((const uint8_t*)data, size); char hash_str[17]; snprintf(hash_str, sizeof(hash_str), "%016" PRIx64, hash); // save to cache_dir/hash_str fs::path cache_file = fs::path(cache_dir) / hash_str; std::ofstream ofs(cache_file, std::ios::binary); ofs.write((const char *)data, size); printf("[%s] saved to '%s'\n", __func__, cache_file.c_str()); } ggml_backend_tensor_set(tensor, data, offset, size); return true; } bool rpc_server::get_cached_file(uint64_t hash, std::vector & data) { if (!cache_dir) { return false; } char hash_str[17]; snprintf(hash_str, sizeof(hash_str), "%016" PRIx64, hash); fs::path cache_file = fs::path(cache_dir) / hash_str; if (!fs::exists(cache_file)) { return false; } std::ifstream ifs(cache_file, std::ios::binary); ifs.seekg(0, std::ios::end); size_t size = ifs.tellg(); ifs.seekg(0, std::ios::beg); data.resize(size); ifs.read((char *)data.data(), size); return true; } bool rpc_server::set_tensor_hash(const rpc_msg_set_tensor_hash_req & request, rpc_msg_set_tensor_hash_rsp & response) { std::vector cached_file; if (!get_cached_file(request.hash, cached_file)) { response.result = 0; return true; } size_t size = cached_file.size(); struct ggml_init_params params { /*.mem_size =*/ ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * tensor = deserialize_tensor(ctx, &request.tensor); if (tensor == nullptr) { GGML_LOG_ERROR("[%s] error deserializing tensor\n", __func__); return false; } GGML_PRINT_DEBUG("[%s] buffer: %p, data: %p, offset: %" PRIu64 ", size: %zu, hash: %" PRIx64 "\n", __func__, (void*)tensor->buffer, tensor->data, request.offset, size, request.hash); // sanitize tensor->data { const size_t p0 = (size_t) ggml_backend_buffer_get_base(tensor->buffer); const size_t p1 = p0 + ggml_backend_buffer_get_size(tensor->buffer); if (request.tensor.data + request.offset < p0 || request.tensor.data + request.offset >= p1 || size > (p1 - request.tensor.data - request.offset)) { GGML_LOG_ERROR("[%s] tensor data region (data=0x%" PRIx64 ", offset=%" PRIu64 ", size=%zu, hash=0x%" PRIx64 ") out of buffer bounds [0x%zx, 0x%zx)\n", __func__, request.tensor.data, request.offset, size, request.hash, p0, p1); return false; } } ggml_backend_tensor_set(tensor, cached_file.data(), request.offset, size); response.result = 1; return true; } bool rpc_server::init_tensor(const rpc_msg_init_tensor_req & request) { struct ggml_init_params params { /*.mem_size =*/ ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * tensor = deserialize_tensor(ctx, &request.tensor); if (tensor == nullptr) { GGML_LOG_ERROR("Null tensor pointer passed to server init_tensor function.\n"); return false; } // Call the backend's buffer_init_tensor function ggml_backend_buffer_t buffer = tensor->buffer; if (buffer && buffer->iface.init_tensor) { buffer->iface.init_tensor(buffer, tensor); } else { GGML_LOG_ERROR("Null buffer for tensor passed to init_tensor function\n"); } if (tensor->extra != nullptr) { // This pointer can either be passed around client/server, or probably better stored server-side and kept track of. // Currently unimplemented. GGML_LOG_ERROR("tensor->extra populated by the backend, this is currently unsupported.\n"); return false; } return true; } bool rpc_server::get_tensor(const rpc_msg_get_tensor_req & request, std::vector & response) { struct ggml_init_params params { /*.mem_size =*/ ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * tensor = deserialize_tensor(ctx, &request.tensor); if (tensor == nullptr) { GGML_LOG_ERROR("[%s] error deserializing tensor\n", __func__); return false; } GGML_PRINT_DEBUG("[%s] buffer: %p, data: %p, offset: %" PRIu64 ", size: %" PRIu64 "\n", __func__, (void*)tensor->buffer, tensor->data, request.offset, request.size); // sanitize tensor->data { const size_t p0 = (size_t) ggml_backend_buffer_get_base(tensor->buffer); const size_t p1 = p0 + ggml_backend_buffer_get_size(tensor->buffer); if (request.tensor.data + request.offset < p0 || request.tensor.data + request.offset >= p1 || request.size > (p1 - request.tensor.data - request.offset)) { GGML_LOG_ERROR("[%s] requested tensor region (data=0x%" PRIx64 ", offset=%" PRIu64 ", size=%" PRIu64 ") out of buffer bounds [0x%zx, 0x%zx)\n", __func__, request.tensor.data, request.offset, request.size, p0, p1); return false; } } response.resize(request.size, 0); ggml_backend_tensor_get(tensor, response.data(), request.offset, request.size); return true; } bool rpc_server::copy_tensor(const rpc_msg_copy_tensor_req & request, rpc_msg_copy_tensor_rsp & response) { struct ggml_init_params params { /*.mem_size =*/ 2*ggml_tensor_overhead(), /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); ggml_tensor * src = deserialize_tensor(ctx, &request.src); ggml_tensor * dst = deserialize_tensor(ctx, &request.dst); if (src == nullptr || dst == nullptr) { GGML_LOG_ERROR("[%s] error deserializing tensors\n", __func__); return false; } uint64_t src_size = (uint64_t) ggml_nbytes(src); uint64_t dst_data = (uint64_t) dst->data; uint64_t dst_base = (uint64_t) ggml_backend_buffer_get_base(dst->buffer); uint64_t dst_buf_sz = (uint64_t) ggml_backend_buffer_get_size(dst->buffer); if (dst_data + src_size > dst_base + dst_buf_sz) { GGML_PRINT_DEBUG("[%s] out-of-bounds write in rpc_server::copy_tensor:\n" " write range : [0x%" PRIx64 ", 0x%" PRIx64 "]\n" " buffer base: [0x%" PRIx64 ", 0x%" PRIx64 "]\n", __func__, dst_data, dst_data + src_size, dst_base, dst_base + dst_buf_sz); return false; } GGML_PRINT_DEBUG("[%s] src->buffer: %p, dst->buffer: %p\n", __func__, (void*) src->buffer, (void*) dst->buffer); response.result = ggml_backend_buffer_copy_tensor(src, dst); return true; } ggml_tensor * rpc_server::create_node(uint64_t id, struct ggml_context * ctx, const std::unordered_map & tensor_ptrs, std::unordered_map & tensor_map) { if (tensor_map.find(id) != tensor_map.end()) { return tensor_map[id]; } // Safely find the tensor pointer auto it_ptr = tensor_ptrs.find(id); if (it_ptr == tensor_ptrs.end()) { return nullptr; } const rpc_tensor * tensor = it_ptr->second; struct ggml_tensor * result = deserialize_tensor(ctx, tensor); if (result == nullptr) { return nullptr; } tensor_map[id] = result; for (int i = 0; i < GGML_MAX_SRC; i++) { // Check if the source ID is 0 before calling create_node recursively if (tensor->src[i] == 0) { result->src[i] = nullptr; } else { result->src[i] = create_node(tensor->src[i], ctx, tensor_ptrs, tensor_map); // If the recursive call failed for a non-zero ID, propagate the error if (result->src[i] == nullptr) { GGML_LOG_ERROR("[%s] failed to create source node %d (src_id=%" PRIu64 ") for node id %" PRIu64 "\n", __func__, i, tensor->src[i], id); // Must return nullptr to signal failure up the call stack return nullptr; } } } // Handle view_src similarly if (tensor->view_src == 0) { result->view_src = nullptr; } else { result->view_src = create_node(tensor->view_src, ctx, tensor_ptrs, tensor_map); // If the recursive call failed for a non-zero ID, propagate the error if (result->view_src == nullptr) { GGML_LOG_ERROR("[%s] failed to create view_src node (view_src_id=%" PRIu64 ") for node id %" PRIu64 "\n", __func__, tensor->view_src, id); // Must return nullptr to signal failure up the call stack return nullptr; } } result->view_offs = tensor->view_offs; return result; } bool rpc_server::graph_compute(const std::vector & input, rpc_msg_graph_compute_rsp & response) { // serialization format: // | n_nodes (4 bytes) | nodes (n_nodes * sizeof(uint64_t) | n_tensors (4 bytes) | tensors (n_tensors * sizeof(rpc_tensor)) | if (input.size() < sizeof(uint32_t)) { return false; } uint32_t n_nodes; memcpy(&n_nodes, input.data(), sizeof(n_nodes)); if (input.size() < sizeof(uint32_t) + n_nodes*sizeof(uint64_t) + sizeof(uint32_t)) { return false; } const uint64_t * nodes = (const uint64_t *)(input.data() + sizeof(n_nodes)); uint32_t n_tensors; memcpy(&n_tensors, input.data() + sizeof(n_nodes) + n_nodes*sizeof(uint64_t), sizeof(n_tensors)); if (input.size() < sizeof(uint32_t) + n_nodes*sizeof(uint64_t) + sizeof(uint32_t) + n_tensors*sizeof(rpc_tensor)) { return false; } const rpc_tensor * tensors = (const rpc_tensor *)(input.data() + sizeof(n_nodes) + n_nodes*sizeof(uint64_t) + sizeof(n_tensors)); GGML_PRINT_DEBUG("[%s] n_nodes: %u, n_tensors: %u\n", __func__, n_nodes, n_tensors); size_t buf_size = ggml_tensor_overhead()*(n_nodes + n_tensors) + ggml_graph_overhead_custom(n_nodes, false); struct ggml_init_params params = { /*.mem_size =*/ buf_size, /*.mem_buffer =*/ NULL, /*.no_alloc =*/ true, }; ggml_context_ptr ctx_ptr { ggml_init(params) }; GGML_ASSERT(ctx_ptr != nullptr); ggml_context * ctx = ctx_ptr.get(); struct ggml_cgraph * graph = ggml_new_graph_custom(ctx, n_nodes, false); graph->n_nodes = n_nodes; std::unordered_map tensor_ptrs; for (uint32_t i = 0; i < n_tensors; i++) { tensor_ptrs[tensors[i].id] = &tensors[i]; } std::unordered_map tensor_map; for (uint32_t i = 0; i < n_nodes; i++) { int64_t id; memcpy(&id, &nodes[i], sizeof(id)); graph->nodes[i] = create_node(id, ctx, tensor_ptrs, tensor_map); // Check if create_node failed for a *non-zero* ID. // If id was 0, create_node returning nullptr is expected. // If id was non-zero and create_node returned nullptr, it indicates a deserialization error. if (graph->nodes[i] == nullptr && id != 0) { GGML_LOG_ERROR("[%s] failed to create graph node %d (id=%" PRId64 ")\n", __func__, i, id); return false; } } ggml_status status = ggml_backend_graph_compute(backend, graph); response.result = status; return true; } rpc_server::~rpc_server() { for (auto buffer : buffers) { ggml_backend_buffer_free(buffer); } } static void rpc_serve_client(ggml_backend_t backend, const char * cache_dir, sockfd_t sockfd, size_t free_mem, size_t total_mem) { rpc_server server(backend, cache_dir); uint8_t cmd; if (!recv_data(sockfd, &cmd, 1)) { return; } // the first command sent by the client must be HELLO if (cmd != RPC_CMD_HELLO) { fprintf(stderr, "Expected HELLO command, update client\n"); return; } if (!recv_msg(sockfd, nullptr, 0)) { return; } rpc_msg_hello_rsp response; server.hello(response); if (!send_msg(sockfd, &response, sizeof(response))) { return; } while (true) { if (!recv_data(sockfd, &cmd, 1)) { break; } if (cmd >= RPC_CMD_COUNT) { // fail fast if the command is invalid fprintf(stderr, "Unknown command: %d\n", cmd); break; } switch (cmd) { case RPC_CMD_HELLO: { // HELLO command is handled above return; } case RPC_CMD_ALLOC_BUFFER: { rpc_msg_alloc_buffer_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } rpc_msg_alloc_buffer_rsp response; server.alloc_buffer(request, response); if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_GET_ALLOC_SIZE: { rpc_msg_get_alloc_size_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } rpc_msg_get_alloc_size_rsp response; if (!server.get_alloc_size(request, response)) { return; } if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_GET_ALIGNMENT: { if (!recv_msg(sockfd, nullptr, 0)) { return; } rpc_msg_get_alignment_rsp response; server.get_alignment(response); if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_GET_MAX_SIZE: { if (!recv_msg(sockfd, nullptr, 0)) { return; } rpc_msg_get_max_size_rsp response; server.get_max_size(response); if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_BUFFER_GET_BASE: { rpc_msg_buffer_get_base_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } rpc_msg_buffer_get_base_rsp response; if (!server.buffer_get_base(request, response)) { return; } if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_FREE_BUFFER: { rpc_msg_free_buffer_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } if (!server.free_buffer(request)) { return; } if (!send_msg(sockfd, nullptr, 0)) { return; } break; } case RPC_CMD_BUFFER_CLEAR: { rpc_msg_buffer_clear_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } if (!server.buffer_clear(request)) { return; } if (!send_msg(sockfd, nullptr, 0)) { return; } break; } case RPC_CMD_SET_TENSOR: { std::vector input; if (!recv_msg(sockfd, input)) { return; } if (!server.set_tensor(input)) { return; } break; } case RPC_CMD_SET_TENSOR_HASH: { rpc_msg_set_tensor_hash_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } rpc_msg_set_tensor_hash_rsp response; if (!server.set_tensor_hash(request, response)) { return; } if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_INIT_TENSOR: { rpc_msg_init_tensor_req request; if (!recv_msg(sockfd, &request,sizeof(request))) { return; } if (!server.init_tensor(request)) { return; } if (!send_msg(sockfd, nullptr, 0)) { return; } break; } case RPC_CMD_GET_TENSOR: { rpc_msg_get_tensor_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } std::vector response; if (!server.get_tensor(request, response)) { return; } if (!send_msg(sockfd, response.data(), response.size())) { return; } break; } case RPC_CMD_COPY_TENSOR: { rpc_msg_copy_tensor_req request; if (!recv_msg(sockfd, &request, sizeof(request))) { return; } rpc_msg_copy_tensor_rsp response; if (!server.copy_tensor(request, response)) { return; } if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_GRAPH_COMPUTE: { std::vector input; if (!recv_msg(sockfd, input)) { return; } rpc_msg_graph_compute_rsp response; if (!server.graph_compute(input, response)) { return; } if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } case RPC_CMD_GET_DEVICE_MEMORY: { if (!recv_msg(sockfd, nullptr, 0)) { return; } rpc_msg_get_device_memory_rsp response; response.free_mem = free_mem; response.total_mem = total_mem; if (!send_msg(sockfd, &response, sizeof(response))) { return; } break; } default: { fprintf(stderr, "Unknown command: %d\n", cmd); return; } } } } void ggml_backend_rpc_start_server(ggml_backend_t backend, const char * endpoint, const char * cache_dir, size_t free_mem, size_t total_mem) { printf("Starting RPC server v%d.%d.%d\n", RPC_PROTO_MAJOR_VERSION, RPC_PROTO_MINOR_VERSION, RPC_PROTO_PATCH_VERSION); printf(" endpoint : %s\n", endpoint); printf(" local cache : %s\n", cache_dir ? cache_dir : "n/a"); printf(" backend memory : %zu MB\n", free_mem / (1024 * 1024)); std::string host; int port; if (!parse_endpoint(endpoint, host, port)) { return; } #ifdef _WIN32 { WSADATA wsaData; int res = WSAStartup(MAKEWORD(2, 2), &wsaData); if (res != 0) { fprintf(stderr, "WSAStartup failed: %d\n", res); return; } } #endif auto server_socket = create_server_socket(host.c_str(), port); if (server_socket == nullptr) { fprintf(stderr, "Failed to create server socket\n"); return; } while (true) { auto client_socket = socket_accept(server_socket->fd); if (client_socket == nullptr) { fprintf(stderr, "Failed to accept client connection\n"); return; } printf("Accepted client connection, free_mem=%zu, total_mem=%zu\n", free_mem, total_mem); fflush(stdout); rpc_serve_client(backend, cache_dir, client_socket->fd, free_mem, total_mem); printf("Client connection closed\n"); fflush(stdout); } #ifdef _WIN32 WSACleanup(); #endif } // device interface struct ggml_backend_rpc_device_context { std::string endpoint; std::string name; }; static const char * ggml_backend_rpc_device_get_name(ggml_backend_dev_t dev) { ggml_backend_rpc_device_context * ctx = (ggml_backend_rpc_device_context *)dev->context; return ctx->name.c_str(); } static const char * ggml_backend_rpc_device_get_description(ggml_backend_dev_t dev) { ggml_backend_rpc_device_context * ctx = (ggml_backend_rpc_device_context *)dev->context; return ctx->name.c_str(); } static void ggml_backend_rpc_device_get_memory(ggml_backend_dev_t dev, size_t * free, size_t * total) { ggml_backend_rpc_device_context * ctx = (ggml_backend_rpc_device_context *)dev->context; ggml_backend_rpc_get_device_memory(ctx->endpoint.c_str(), free, total); GGML_UNUSED(dev); } static enum ggml_backend_dev_type ggml_backend_rpc_device_get_type(ggml_backend_dev_t dev) { // TODO: obtain value from the server return GGML_BACKEND_DEVICE_TYPE_GPU; GGML_UNUSED(dev); } static void ggml_backend_rpc_device_get_props(ggml_backend_dev_t dev, struct ggml_backend_dev_props * props) { props->name = ggml_backend_rpc_device_get_name(dev); props->description = ggml_backend_rpc_device_get_description(dev); props->type = ggml_backend_rpc_device_get_type(dev); ggml_backend_rpc_device_get_memory(dev, &props->memory_free, &props->memory_total); props->caps = { /* .async = */ false, /* .host_buffer = */ false, /* .buffer_from_host_ptr = */ false, /* .events = */ false, }; } static ggml_backend_t ggml_backend_rpc_device_init(ggml_backend_dev_t dev, const char * params) { ggml_backend_rpc_device_context * ctx = (ggml_backend_rpc_device_context *)dev->context; return ggml_backend_rpc_init(ctx->endpoint.c_str()); GGML_UNUSED(params); } static ggml_backend_buffer_type_t ggml_backend_rpc_device_get_buffer_type(ggml_backend_dev_t dev) { ggml_backend_rpc_device_context * ctx = (ggml_backend_rpc_device_context *)dev->context; return ggml_backend_rpc_buffer_type(ctx->endpoint.c_str()); GGML_UNUSED(dev); } static bool ggml_backend_rpc_device_supports_op(ggml_backend_dev_t dev, const struct ggml_tensor * op) { GGML_UNUSED(dev); GGML_UNUSED(op); //TODO: call the remote backend and cache the results return true; } static bool ggml_backend_rpc_device_supports_buft(ggml_backend_dev_t dev, ggml_backend_buffer_type_t buft) { if (!buft || buft->iface.get_name != ggml_backend_rpc_buffer_type_name) { return false; } ggml_backend_rpc_buffer_type_context * buft_ctx = (ggml_backend_rpc_buffer_type_context *)buft->context; ggml_backend_rpc_device_context * dev_ctx = (ggml_backend_rpc_device_context *)dev->context; return buft_ctx->endpoint == dev_ctx->endpoint; } static const struct ggml_backend_device_i ggml_backend_rpc_device_i = { /* .get_name = */ ggml_backend_rpc_device_get_name, /* .get_description = */ ggml_backend_rpc_device_get_description, /* .get_memory = */ ggml_backend_rpc_device_get_memory, /* .get_type = */ ggml_backend_rpc_device_get_type, /* .get_props = */ ggml_backend_rpc_device_get_props, /* .init_backend = */ ggml_backend_rpc_device_init, /* .get_buffer_type = */ ggml_backend_rpc_device_get_buffer_type, /* .get_host_buffer_type = */ NULL, /* .buffer_from_host_ptr = */ NULL, /* .supports_op = */ ggml_backend_rpc_device_supports_op, /* .supports_buft = */ ggml_backend_rpc_device_supports_buft, /* .offload_op = */ NULL, /* .event_new = */ NULL, /* .event_free = */ NULL, /* .event_synchronize = */ NULL, }; // backend reg interface static const char * ggml_backend_rpc_reg_get_name(ggml_backend_reg_t reg) { return "RPC"; GGML_UNUSED(reg); } static size_t ggml_backend_rpc_reg_get_device_count(ggml_backend_reg_t reg) { return 0; GGML_UNUSED(reg); } static ggml_backend_dev_t ggml_backend_rpc_reg_get_device(ggml_backend_reg_t reg, size_t index) { GGML_ABORT("The RPC backend does not have enumerated devices - use ggml_backend_add_device instead"); GGML_UNUSED(reg); GGML_UNUSED(index); } static void * ggml_backend_rpc_get_proc_address(ggml_backend_reg_t reg, const char * name) { if (std::strcmp(name, "ggml_backend_rpc_add_device") == 0) { return (void *)ggml_backend_rpc_add_device; } if (std::strcmp(name, "ggml_backend_rpc_start_server") == 0) { return (void *)ggml_backend_rpc_start_server; } return NULL; GGML_UNUSED(reg); } static const struct ggml_backend_reg_i ggml_backend_rpc_reg_i = { /* .get_name = */ ggml_backend_rpc_reg_get_name, /* .get_device_count = */ ggml_backend_rpc_reg_get_device_count, /* .get_device = */ ggml_backend_rpc_reg_get_device, /* .get_proc_address = */ ggml_backend_rpc_get_proc_address, }; ggml_backend_reg_t ggml_backend_rpc_reg(void) { static struct ggml_backend_reg ggml_backend_rpc_reg = { /* .api_version = */ GGML_BACKEND_API_VERSION, /* .iface = */ ggml_backend_rpc_reg_i, /* .context = */ NULL, }; return &ggml_backend_rpc_reg; } ggml_backend_dev_t ggml_backend_rpc_add_device(const char * endpoint) { static std::unordered_map dev_map; static std::mutex mutex; std::lock_guard lock(mutex); if (dev_map.find(endpoint) != dev_map.end()) { return dev_map[endpoint]; } ggml_backend_rpc_device_context * ctx = new ggml_backend_rpc_device_context { /* .endpoint = */ endpoint, /* .name = */ "RPC[" + std::string(endpoint) + "]", }; ggml_backend_dev_t dev = new ggml_backend_device { /* .iface = */ ggml_backend_rpc_device_i, /* .reg = */ ggml_backend_rpc_reg(), /* .context = */ ctx, }; dev_map[endpoint] = dev; return dev; } GGML_BACKEND_DL_IMPL(ggml_backend_rpc_reg)