syntax = "proto2"; package caffe2; // A few notes about the Caffe2's protobuffer convention: // (1) Most objects are registered by their types, such as operators and nets. // For these, we have a string-type field "type" for registration purposes. // (2) We do not use extension because that used to create quite some conflicts // in Caffe's protobuf design. // (3) We have not used any proto3 specific features, such as Any or Map. This // is mainly for backward compatibility purposes but we may consider using // those in the future. // TensorProto stores serialized Tensor objects. message TensorProto { // The dimensions in the tensor. repeated int64 dims = 1; // Data type enum DataType { UNDEFINED = 0; // Basic types FLOAT = 1; // float INT32 = 2; // int BYTE = 3; // byte, when deserialized, is going to be restored as uint8 STRING = 4; // string // Less-commonly used data types BOOL = 5; // bool UINT8 = 6; // uint8_t INT8 = 7; // int8_t UINT16 = 8; // uint16_t INT16 = 9; // int16_t INT64 = 10; // int64_t FLOAT16 = 12; // at::Half DOUBLE = 13; // double ZERO_COLLISION_HASH = 14; // zero-collision hash state REBATCHING_BUFFER = 15; // rebatching buffer } // The type of the deserialized tensor data optional DataType data_type = 2 [ default = FLOAT ]; // The format of the serialized data. enum SerializationFormat { // FMT_PROTOBUF is the existing serialization format from before the // data_format field was introduced. Most data types are serialized using // the protobuf typed fields, although in some cases raw little endian data // is stored in the byte_data field instead. FMT_PROTOBUF = 0; // bfloat16 data stored in the raw_data field. FMT_BFLOAT16 = 1; } // data_format is a SerializationFormat enum value. // However, we intentionally store it as an integer value so we can // distinguish between old messages that do not have a data_format value vs // new messages that have a SerializationFormat value that we don't // understand. If we stored this as an enum then protobuf would deserialize // both of these cases the same way. optional uint32 data_format = 15 [ default = 0 ]; // For float repeated float float_data = 3 [ packed = true ]; // For int32, uint8, int8, uint16, int16, bool, and float16 // Note about float16: in storage we will basically convert float16 byte-wise // to unsigned short and then store them in the int32_data field. // Note: storing int8 and uint8 values in this field unfortunately results in // larger serialized data than necessary, as protobuf's varint encoding // scheme requires 2 bytes to represent int8 and uint8 values that have the // MSB set. repeated int32 int32_data = 4 [ packed = true ]; // For bytes optional bytes byte_data = 5; // For strings repeated bytes string_data = 6; // For double repeated double double_data = 9 [ packed = true ]; // For int64 repeated int64 int64_data = 10 [ packed = true ]; // store the raw data, contents are serialized as little-endian optional bytes raw_data = 13; // Optionally, a name for the tensor. optional string name = 7; // Optionally, a TensorProto can contain the details about the device that // it was serialized from. This is useful in cases like snapshotting a whole // workspace in a multi-GPU environment. optional DeviceOption device_detail = 8; // When loading from chunks this is going to indicate where to put data in the // full array. When not used full data have to be present message Segment { required int64 begin = 1; required int64 end = 2; } optional Segment segment = 11; // Field numbers 12 and 14 were previously used for now-deprecated fields. // reserved 12, 14; } message QTensorProto { repeated int64 dims = 1; required int32 precision = 2; required double scale = 3; required double bias = 4; required bool is_signed = 5; repeated int32 data = 6 [ packed = true ]; optional string name = 7; optional TensorProto.DataType data_type = 8 [ default = INT32 ]; // Multi-group quantization params repeated double scales = 9; repeated double biases = 10; // Multi-group quantization needed, indicates in which dimension // we do the "group wise quantization" optional int32 axis = 11; // It should be true if it is a multi-group quantization proto optional bool is_multiparam = 12 [ default = false ]; } // TensorProtos stores multiple TensorProto objects in one single proto. This // is useful for small tensors; For anything big, consider using a DB for // storage. message TensorProtos { repeated TensorProto protos = 1; } message TensorShape { repeated int64 dims = 1; optional TensorProto.DataType data_type = 2 [ default = FLOAT ]; repeated int32 unknown_dims = 3; optional bool unknown_shape = 4 [ default = false ]; optional string name = 5; } message TensorShapes { repeated TensorShape shapes = 1; } // TensorBoundShape is used to save bound shape inference result for a tensor. // TensorBoundShape.shape is inferred shape for this tensor. // TensorBoundShape.dimType contains dim_type for every dimension. // eg: for dimension i, shape.dims[i] is the inferred shape and // dim_type[i] is corresponding dim_type. message TensorBoundShape { optional TensorShape shape = 1; enum DimType { UNKNOWN = 0; // unknown CONSTANT = 1; // constant // batch, corresponding dimension is batch_size BATCH = 2; // batch_of_feature_max, // corresponding shape is inferred_feature_length * batch_size BATCH_OF_FEATURE_MAX = 3; // batch_of_feature_max_default // corresponding shape is default_feature_length * batch_size BATCH_OF_FEATURE_MAX_DEFAULT = 4; // feature_max, corresponding shape is inferred_feature_length FEATURE_MAX = 5; // feature_max_default, corresponding shape is default_feature_length FEATURE_MAX_DEFAULT = 6; } repeated DimType dim_type = 2; // dim_type.size() == shape.dims.size() optional string name = 3; // a flag to indicate whether the shape is final and cannot be changed // eg: input/output of in-place ops optional bool shape_is_final = 4; } message TensorBoundShapes { repeated TensorBoundShape shapes = 1; optional int64 max_batch_size = 2; optional int64 max_feature_len = 3; } message AOTConfig { required int64 max_batch_size = 1; required int64 max_seq_size = 2; required bool in_batch_broadcast = 3; optional string onnxifi_blacklist_ops = 4; optional int32 onnxifi_min_ops = 5; } // A named argument containing either singular float, integer and string // values, or repeated float, int and string arrays. message Argument { optional string name = 1; optional float f = 2; optional int64 i = 3; optional bytes s = 4; optional TensorProto t = 10; optional NetDef n = 8; repeated float floats = 5; repeated int64 ints = 6; repeated bytes strings = 7; repeated TensorProto tensors = 11; repeated NetDef nets = 9; repeated QTensorProto qtensors = 12; } // DeviceType that Caffe2 currently supports. // Note: if you add a device type, make sure you add the corresponding device // line in the DeviceTypeName() function in caffe2/utils/proto_utils.cc // and update c10/core/DeviceType.h enum DeviceTypeProto { PROTO_CPU = 0; // In default, we will use CPU. PROTO_CUDA = 1; // CUDA. PROTO_MKLDNN = 2; // Reserved for explicit MKLDNN PROTO_OPENGL = 3; // OpenGL PROTO_OPENCL = 4; // OpenCL PROTO_IDEEP = 5; // IDEEP. PROTO_HIP = 6; // AMD HIP PROTO_FPGA = 7; // FPGA PROTO_ORT = 8; // ONNX Runtime PROTO_XLA = 9; // XLA / TPU PROTO_MLC = 10; // ML Compute // Change the following number if you add more devices in the code. PROTO_COMPILE_TIME_MAX_DEVICE_TYPES = 11; } // Device-specific options. We do not distinguish DeviceOption protos for // different DeviceTypes, so currently all devices share the same DeviceOption // proto. Fields that are specific to a device type is ignored if the type does // not match. // Note: if you add fields to the DeviceOption, make sure you add the // corresponding changes to IsSameDevice() function in utils/proto_utils.{h,cc}. message DeviceOption { // [general] Options that need to be carried out before running the execution. // optional DeviceType device_type = 1 [ default = CPU ]; optional int32 device_type = 1 [ default = 0 ]; // 0 is CPU. // [general] Used together with device_type to identify the exact device optional int32 device_id = 2; // [general] The random seed to start the device random number generator with. optional uint32 random_seed = 3; // [general] What node this op should execute on. // Used for net transformation purposes. Must be empty at execution time. optional string node_name = 4; // [CPU and Linux specific] NUMA node id optional int32 numa_node_id = 5; // [general] Extra information passed, not used at execution time currently. repeated string extra_info = 6; } // Operator Definition. message OperatorDef { repeated string input = 1; // the name of the input blobs repeated string output = 2; // the name of output top blobs optional string name = 3; // the operator name. This is optional. // the operator type. This is needed to create the object from the operator // registry. optional string type = 4; // arg is for the argument defined in operator schema repeated Argument arg = 5; // The device option that the operator should run under. optional DeviceOption device_option = 6; // Optionally, one can specify an engine when there are multiple // implementations available simultaneously for one device type. // If one specifies an engine but that engine does not exist in the compiled // Caffe2 binary, Caffe2 will fall back to the default engine of that device // type. optional string engine = 7; // Additional 'fake' inputs used for expressing control dependencies // in the operator graph. This can be used to ensure that an // operator does not run until another operator is ready, for e.g. // scheduling control. These are not passed as actual inputs to the // Operator implementation, and are only used by the Net class for // scheduling purposes. repeated string control_input = 8; // is_gradient_op argument is only used as a hint in shape inference // and has no runtime significance optional bool is_gradient_op = 9 [ default = false ]; // debug information associated with the construction of the operator. // This is an optional string with no assumed characteristics as // operators can be constructed in any language. optional string debug_info = 10; // the domain of the operator to help runtime distinguish which operator // library this OperatorDef refers to. For example, both caffe2 and aten // has `Add` operator, with domain, we can easily decide which operator // to execute. to support multiple operator libs, we use domain to // distinguish which operator lib we refer to: // - "caffe2" means this uses Caffe2 operator library // - "aten" means this uses ATen operator library // - "c10" is for the fused library // - if the domain is missing or empty, we use "caffe2", this is for // legacy models, new serializer should always export an OperatorDef // with domain and op_version optional string domain = 11; // each operator is has its own version number. // operator version information // each time, we change the API or semantics of the operator, // we bump the version for the operator. // the runtime system should check the op_version of each OperatorDef // and decide it should reject or accept the model optional int64 op_version = 12; } // MapFieldEntry follows the pattern for cross-proto-version maps. // See https://developers.google.com/protocol-buffers/docs/proto3#maps message MapFieldEntry { required string key = 1; required string val = 2; }; // Used to hold backend-specific options. message BackendOptions { // Name of the backend that the specified options apply to. required string backend_name = 1; // Flexible map for passing in the options. repeated MapFieldEntry option = 2; }; // Partition definition. message PartitionInfo { // Name of the partition. required string name = 1; // A list of logic device ID, indicating which devices this partition // can be executed on. If empty, it means the partition won't run on // device but on host CPU instead. repeated int32 device_id = 2; // Extra debug info. optional string extra_info = 3; // Flexible map for passing options specific to a backend. repeated BackendOptions backend_options = 4; } // Network definition. message NetDef { optional string name = 1; // the network's name // Operators that the network contains. // Note: this is not named "operator" because that is a reserved word in C++. repeated OperatorDef op = 2; // The type of network that the net should be run with. This routes the // network instantiation to different execution modes. The default mode, // "simple", runs the operators in a sequential way as the original Caffe // implementation does. optional string type = 3; // the number of workers, if the operators in the network is to be carried out // in parallel. // Note: This is to be deprecated. Using the arg field with "num_workers" as // key. // Note 2: The old uses of this were never actually cleaned up optional int32 num_workers = 4; // The device option for the network. If a network has a specific device // option and one of its operators does not have it set, we will copy over the // device option to the operator. This allows us to basically avoid putting // device options at every operator. optional DeviceOption device_option = 5; repeated Argument arg = 6; // Two optional fields to declare external input and output of a net. // If these two are set, when a net is created, we will sanity check for // every op whether its input is declared (either as an external input, // or as an intermediate blob created by one of the ops), and sanity check // if all blobs in external_output are produced. // // In cases of memory optimization, declaring external_input and // external_output also ensures that storage of these blobs are persistent: // for any blob in external_input and external_output, after a network run // finishes, their content are actually the right content. Any intermediate // blobs' contents may be overwritten. repeated string external_input = 7; repeated string external_output = 8; // Partitioning info, indexed by partition names. repeated PartitionInfo partition_info = 9; } // ExecutionStep is actually a sort-of-hacky way we simulate iteration right // now. message ExecutionStep { // ExecutionStep should either contain a set of substeps, or a set of // network names to run in this execution step. They should NOT both be set // at the same time. optional string name = 1; // An execution step could be recursive, in which it involves a set of // substeps. repeated ExecutionStep substep = 2; // Alternatively, an execution step could involve one or more networks. // Note that you cannot have both substeps and networks. Choose one. // Note that an execution step refers networks by their name. The actual // network definition of the same name should be included in the network field // of the plan. The reason is that a network object might hold internal states // (think of a data layer), so we want to have the same network object that // multiple steps could ask to run. repeated string network = 3; // Number of iterations to run this step. The substeps or the networks // specified will be run sequentially, and one sequential run is considered // one iteration. If this is not set, the number of iterations is assumed to // be 1. optional int64 num_iter = 4; // Criteria network specifies a single output (TensorCPU) of // size (1), is run on every iteration by the executor, and // execution terminates when the output[0] is `false`. optional string criteria_network = 5 [ deprecated = true ]; // DEPRECATED. Use `run_every_ms`. optional string report_net = 7; optional int32 report_interval = 8; // If provided, execute this step at every time interval (in millisecs) // while its sibiling execution steps execute in parallel. This step is // guaranteed to run at least once after all non-interval siblings finished. optional int64 run_every_ms = 11; // If false or not set, execute sub-steps serially. // If true, execute all substeps concurrently, each one in a separate thread. optional bool concurrent_substeps = 6; // Name of a scalar boolean tensor. // ES checks this blob AFTER every substeps/subnets. // If specified, and the value is true, then ES will skip the rest and return // immediately. // This means that the report_net and the first step will always be called. // Use cases: // 1) the first substep stops the rest if data condition not met // 2) the first substep decide which of the rest of the steps should be run. // 3) external control // // ** It is the user's responsibility to not to put this blob in race // conditions. // ** For example when setting this blob in concurrent substeps optional string should_stop_blob = 9; // if only_once is true, this step will only be executed once. this ONLY takes // effect when using should_stop_blob optional bool only_once = 10; // Whether to create a child workspace for this step. // If yes, the workflow and nets are re-created every time this step is run. optional bool create_workspace = 12; // How many copies of the children execution steps to run concurrently. optional int32 num_concurrent_instances = 13; } message PlanDef { // All the networks that are used in this execution. Note that networks should // be ordered in the way they are executed, i.e. for a layer in a network, all // its input blobs should already have been initialized by the layers or // networks defined before it. optional string name = 1; // The networks that are going to be used in this plan. repeated NetDef network = 2; repeated ExecutionStep execution_step = 3; } // Protobuf format for blobs that are not Tensors. We use a key to store the // type of the blob. For example for a serialized DBProto, the type should // be "DBReader" and the content should be a serialized DBProto object. message BlobProto { optional string name = 1; optional string type = 2; optional TensorProto tensor = 3; optional bytes content = 4; optional QTensorProto qtensor = 5; // If blob is not Tensor and is divided into chunks, content_num_chunks // contains number of chunks, into which blob was divided. optional int32 content_num_chunks = 6; optional int32 content_chunk_id = 7; } // Protobuf format to serialize DBReader. message DBReaderProto { // The name for the DB object in the workspace. optional string name = 1; // The source of the DB optional string source = 2; // The type of the DB optional string db_type = 3; // The current key of the DB if the DB supports seeking. optional string key = 4; } message BlobSerializationOptions { // This set of options will only apply to blobs whose name matches this // pattern. If the blob_name_pattern is empty then it will be treated as // matching all blobs. optional string blob_name_regex = 1; // Note: // - a chunk_size of 0 means "use the default chunk size". The default chunk // size is controlled by the --caffe2_tensor_chunk_size command line flag. // - a chunk size of -1 means to disable chunking, and serialize the blob in // a single chunk. optional int64 chunk_size = 2; enum FloatFormat { // Use the current default serialization format, as chosen by the // current version of the code. (At the time of writing this is PROTOBUF) FLOAT_DEFAULT = 0; // Store the data in the TensorProto's float_data field FLOAT_PROTOBUF = 1; // Serialize float values as bfloat16. Note that this conversion is lossy. FLOAT_BFLOAT16 = 2; } // Settings for how to serialize tensors containing float values optional FloatFormat float_format = 3; } message SerializationOptions { // A set of options to use when serialializing blobs. // This is a list, sorted from highest to lowest precedence. When // serializing a blob, the first entry whose blob_name_pattern matches the // blob name will be used. repeated BlobSerializationOptions options = 1; }