third_party/googleapis/google/devtools/clouddebugger/v2/data.proto - bazel - Git at Google

 // Copyright 2017 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 syntax = "proto3";

 package google.devtools.clouddebugger.v2;

 import "google/api/annotations.proto";
 import "google/devtools/source/v1/source_context.proto";
 import "google/protobuf/timestamp.proto";
 import "google/protobuf/wrappers.proto";

 option go_package = "google.golang.org/genproto/googleapis/devtools/clouddebugger/v2;clouddebugger";
 option java_multiple_files = true;
 option java_outer_classname = "DataProto";
 option java_package = "com.google.devtools.clouddebugger.v2";


 // Represents a message with parameters.
 message FormatMessage {
   // Format template for the message. The `format` uses placeholders `$0`,
   // `$1`, etc. to reference parameters. `$$` can be used to denote the `$`
   // character.
   //
   // Examples:
   //
   // *   `Failed to load '$0' which helps debug $1 the first time it
   //     is loaded.  Again, $0 is very important.`
   // *   `Please pay $$10 to use $0 instead of $1.`
   string format = 1;

   // Optional parameters to be embedded into the message.
   repeated string parameters = 2;
 }

 // Represents a contextual status message.
 // The message can indicate an error or informational status, and refer to
 // specific parts of the containing object.
 // For example, the `Breakpoint.status` field can indicate an error referring
 // to the `BREAKPOINT_SOURCE_LOCATION` with the message `Location not found`.
 message StatusMessage {
   // Enumerates references to which the message applies.
   enum Reference {
     // Status doesn't refer to any particular input.
     UNSPECIFIED = 0;

     // Status applies to the breakpoint and is related to its location.
     BREAKPOINT_SOURCE_LOCATION = 3;

     // Status applies to the breakpoint and is related to its condition.
     BREAKPOINT_CONDITION = 4;

     // Status applies to the breakpoint and is related to its expressions.
     BREAKPOINT_EXPRESSION = 7;

     // Status applies to the breakpoint and is related to its age.
     BREAKPOINT_AGE = 8;

     // Status applies to the entire variable.
     VARIABLE_NAME = 5;

     // Status applies to variable value (variable name is valid).
     VARIABLE_VALUE = 6;
   }

   // Distinguishes errors from informational messages.
   bool is_error = 1;

   // Reference to which the message applies.
   Reference refers_to = 2;

   // Status message text.
   FormatMessage description = 3;
 }

 // Represents a location in the source code.
 message SourceLocation {
   // Path to the source file within the source context of the target binary.
   string path = 1;

   // Line inside the file. The first line in the file has the value `1`.
   int32 line = 2;
 }

 // Represents a variable or an argument possibly of a compound object type.
 // Note how the following variables are represented:
 //
 // 1) A simple variable:
 //
 //     int x = 5
 //
 //     { name: "x", value: "5", type: "int" }  // Captured variable
 //
 // 2) A compound object:
 //
 //     struct T {
 //         int m1;
 //         int m2;
 //     };
 //     T x = { 3, 7 };
 //
 //     {  // Captured variable
 //         name: "x",
 //         type: "T",
 //         members { name: "m1", value: "3", type: "int" },
 //         members { name: "m2", value: "7", type: "int" }
 //     }
 //
 // 3) A pointer where the pointee was captured:
 //
 //     T x = { 3, 7 };
 //     T* p = &x;
 //
 //     {   // Captured variable
 //         name: "p",
 //         type: "T*",
 //         value: "0x00500500",
 //         members { name: "m1", value: "3", type: "int" },
 //         members { name: "m2", value: "7", type: "int" }
 //     }
 //
 // 4) A pointer where the pointee was not captured:
 //
 //     T* p = new T;
 //
 //     {   // Captured variable
 //         name: "p",
 //         type: "T*",
 //         value: "0x00400400"
 //         status { is_error: true, description { format: "unavailable" } }
 //     }
 //
 // The status should describe the reason for the missing value,
 // such as `<optimized out>`, `<inaccessible>`, `<pointers limit reached>`.
 //
 // Note that a null pointer should not have members.
 //
 // 5) An unnamed value:
 //
 //     int* p = new int(7);
 //
 //     {   // Captured variable
 //         name: "p",
 //         value: "0x00500500",
 //         type: "int*",
 //         members { value: "7", type: "int" } }
 //
 // 6) An unnamed pointer where the pointee was not captured:
 //
 //     int* p = new int(7);
 //     int** pp = &p;
 //
 //     {  // Captured variable
 //         name: "pp",
 //         value: "0x00500500",
 //         type: "int**",
 //         members {
 //             value: "0x00400400",
 //             type: "int*"
 //             status {
 //                 is_error: true,
 //                 description: { format: "unavailable" } }
 //             }
 //         }
 //     }
 //
 // To optimize computation, memory and network traffic, variables that
 // repeat in the output multiple times can be stored once in a shared
 // variable table and be referenced using the `var_table_index` field.  The
 // variables stored in the shared table are nameless and are essentially
 // a partition of the complete variable. To reconstruct the complete
 // variable, merge the referencing variable with the referenced variable.
 //
 // When using the shared variable table, the following variables:
 //
 //     T x = { 3, 7 };
 //     T* p = &x;
 //     T& r = x;
 //
 //     { name: "x", var_table_index: 3, type: "T" }  // Captured variables
 //     { name: "p", value "0x00500500", type="T*", var_table_index: 3 }
 //     { name: "r", type="T&", var_table_index: 3 }
 //
 //     {  // Shared variable table entry #3:
 //         members { name: "m1", value: "3", type: "int" },
 //         members { name: "m2", value: "7", type: "int" }
 //     }
 //
 // Note that the pointer address is stored with the referencing variable
 // and not with the referenced variable. This allows the referenced variable
 // to be shared between pointers and references.
 //
 // The type field is optional. The debugger agent may or may not support it.
 message Variable {
   // Name of the variable, if any.
   string name = 1;

   // Simple value of the variable.
   string value = 2;

   // Variable type (e.g. `MyClass`). If the variable is split with
   // `var_table_index`, `type` goes next to `value`. The interpretation of
   // a type is agent specific. It is recommended to include the dynamic type
   // rather than a static type of an object.
   string type = 6;

   // Members contained or pointed to by the variable.
   repeated Variable members = 3;

   // Reference to a variable in the shared variable table. More than
   // one variable can reference the same variable in the table. The
   // `var_table_index` field is an index into `variable_table` in Breakpoint.
   google.protobuf.Int32Value var_table_index = 4;

   // Status associated with the variable. This field will usually stay
   // unset. A status of a single variable only applies to that variable or
   // expression. The rest of breakpoint data still remains valid. Variables
   // might be reported in error state even when breakpoint is not in final
   // state.
   //
   // The message may refer to variable name with `refers_to` set to
   // `VARIABLE_NAME`. Alternatively `refers_to` will be set to `VARIABLE_VALUE`.
   // In either case variable value and members will be unset.
   //
   // Example of error message applied to name: `Invalid expression syntax`.
   //
   // Example of information message applied to value: `Not captured`.
   //
   // Examples of error message applied to value:
   //
   // *   `Malformed string`,
   // *   `Field f not found in class C`
   // *   `Null pointer dereference`
   StatusMessage status = 5;
 }

 // Represents a stack frame context.
 message StackFrame {
   // Demangled function name at the call site.
   string function = 1;

   // Source location of the call site.
   SourceLocation location = 2;

   // Set of arguments passed to this function.
   // Note that this might not be populated for all stack frames.
   repeated Variable arguments = 3;

   // Set of local variables at the stack frame location.
   // Note that this might not be populated for all stack frames.
   repeated Variable locals = 4;
 }

 // Represents the breakpoint specification, status and results.
 message Breakpoint {
   // Actions that can be taken when a breakpoint hits.
   // Agents should reject breakpoints with unsupported or unknown action values.
   enum Action {
     // Capture stack frame and variables and update the breakpoint.
     // The data is only captured once. After that the breakpoint is set
     // in a final state.
     CAPTURE = 0;

     // Log each breakpoint hit. The breakpoint remains active until
     // deleted or expired.
     LOG = 1;
   }

   // Log severity levels.
   enum LogLevel {
     // Information log message.
     INFO = 0;

     // Warning log message.
     WARNING = 1;

     // Error log message.
     ERROR = 2;
   }

   // Breakpoint identifier, unique in the scope of the debuggee.
   string id = 1;

   // Action that the agent should perform when the code at the
   // breakpoint location is hit.
   Action action = 13;

   // Breakpoint source location.
   SourceLocation location = 2;

   // Condition that triggers the breakpoint.
   // The condition is a compound boolean expression composed using expressions
   // in a programming language at the source location.
   string condition = 3;

   // List of read-only expressions to evaluate at the breakpoint location.
   // The expressions are composed using expressions in the programming language
   // at the source location. If the breakpoint action is `LOG`, the evaluated
   // expressions are included in log statements.
   repeated string expressions = 4;

   // Only relevant when action is `LOG`. Defines the message to log when
   // the breakpoint hits. The message may include parameter placeholders `$0`,
   // `$1`, etc. These placeholders are replaced with the evaluated value
   // of the appropriate expression. Expressions not referenced in
   // `log_message_format` are not logged.
   //
   // Example: `Message received, id = $0, count = $1` with
   // `expressions` = `[ message.id, message.count ]`.
   string log_message_format = 14;

   // Indicates the severity of the log. Only relevant when action is `LOG`.
   LogLevel log_level = 15;

   // When true, indicates that this is a final result and the
   // breakpoint state will not change from here on.
   bool is_final_state = 5;

   // Time this breakpoint was created by the server in seconds resolution.
   google.protobuf.Timestamp create_time = 11;

   // Time this breakpoint was finalized as seen by the server in seconds
   // resolution.
   google.protobuf.Timestamp final_time = 12;

   // E-mail address of the user that created this breakpoint
   string user_email = 16;

   // Breakpoint status.
   //
   // The status includes an error flag and a human readable message.
   // This field is usually unset. The message can be either
   // informational or an error message. Regardless, clients should always
   // display the text message back to the user.
   //
   // Error status indicates complete failure of the breakpoint.
   //
   // Example (non-final state): `Still loading symbols...`
   //
   // Examples (final state):
   //
   // *   `Invalid line number` referring to location
   // *   `Field f not found in class C` referring to condition
   StatusMessage status = 10;

   // The stack at breakpoint time.
   repeated StackFrame stack_frames = 7;

   // Values of evaluated expressions at breakpoint time.
   // The evaluated expressions appear in exactly the same order they
   // are listed in the `expressions` field.
   // The `name` field holds the original expression text, the `value` or
   // `members` field holds the result of the evaluated expression.
   // If the expression cannot be evaluated, the `status` inside the `Variable`
   // will indicate an error and contain the error text.
   repeated Variable evaluated_expressions = 8;

   // The `variable_table` exists to aid with computation, memory and network
   // traffic optimization.  It enables storing a variable once and reference
   // it from multiple variables, including variables stored in the
   // `variable_table` itself.
   // For example, the same `this` object, which may appear at many levels of
   // the stack, can have all of its data stored once in this table.  The
   // stack frame variables then would hold only a reference to it.
   //
   // The variable `var_table_index` field is an index into this repeated field.
   // The stored objects are nameless and get their name from the referencing
   // variable. The effective variable is a merge of the referencing variable
   // and the referenced variable.
   repeated Variable variable_table = 9;

   // A set of custom breakpoint properties, populated by the agent, to be
   // displayed to the user.
   map<string, string> labels = 17;
 }

 // Represents the application to debug. The application may include one or more
 // replicated processes executing the same code. Each of these processes is
 // attached with a debugger agent, carrying out the debugging commands.
 // The agents attached to the same debuggee are identified by using exactly the
 // same field values when registering.
 message Debuggee {
   // Unique identifier for the debuggee generated by the controller service.
   string id = 1;

   // Project the debuggee is associated with.
   // Use the project number when registering a Google Cloud Platform project.
   string project = 2;

   // Debuggee uniquifier within the project.
   // Any string that identifies the application within the project can be used.
   // Including environment and version or build IDs is recommended.
   string uniquifier = 3;

   // Human readable description of the debuggee.
   // Including a human-readable project name, environment name and version
   // information is recommended.
   string description = 4;

   // If set to `true`, indicates that the debuggee is considered as inactive by
   // the Controller service.
   bool is_inactive = 5;

   // Version ID of the agent release. The version ID is structured as
   // following: `domain/type/vmajor.minor` (for example
   // `google.com/gcp-java/v1.1`).
   string agent_version = 6;

   // If set to `true`, indicates that the agent should disable itself and
   // detach from the debuggee.
   bool is_disabled = 7;

   // Human readable message to be displayed to the user about this debuggee.
   // Absence of this field indicates no status. The message can be either
   // informational or an error status.
   StatusMessage status = 8;

   // References to the locations and revisions of the source code used in the
   // deployed application.
   //
   // NOTE: This field is deprecated. Consumers should use
   // `ext_source_contexts` if it is not empty. Debug agents should populate
   // both this field and `ext_source_contexts`.
   repeated google.devtools.source.v1.SourceContext source_contexts = 9;

   // References to the locations and revisions of the source code used in the
   // deployed application.
   //
   // Contexts describing a remote repo related to the source code
   // have a `category` label of `remote_repo`. Source snapshot source
   // contexts have a `category` of `snapshot`.
   repeated google.devtools.source.v1.ExtendedSourceContext ext_source_contexts = 13;

   // A set of custom debuggee properties, populated by the agent, to be
   // displayed to the user.
   map<string, string> labels = 11;
 }
	// Copyright 2017 Google Inc.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	syntax = "proto3";

	package google.devtools.clouddebugger.v2;

	import "google/api/annotations.proto";
	import "google/devtools/source/v1/source_context.proto";
	import "google/protobuf/timestamp.proto";
	import "google/protobuf/wrappers.proto";

	option go_package = "google.golang.org/genproto/googleapis/devtools/clouddebugger/v2;clouddebugger";
	option java_multiple_files = true;
	option java_outer_classname = "DataProto";
	option java_package = "com.google.devtools.clouddebugger.v2";


	// Represents a message with parameters.
	message FormatMessage {
	// Format template for the message. The `format` uses placeholders `$0`,
	// `$1`, etc. to reference parameters. `$$` can be used to denote the `$`
	// character.
	//
	// Examples:
	//
	// * `Failed to load '$0' which helps debug $1 the first time it
	// is loaded. Again, $0 is very important.`
	// * `Please pay $$10 to use $0 instead of $1.`
	string format = 1;

	// Optional parameters to be embedded into the message.
	repeated string parameters = 2;
	}

	// Represents a contextual status message.
	// The message can indicate an error or informational status, and refer to
	// specific parts of the containing object.
	// For example, the `Breakpoint.status` field can indicate an error referring
	// to the `BREAKPOINT_SOURCE_LOCATION` with the message `Location not found`.
	message StatusMessage {
	// Enumerates references to which the message applies.
	enum Reference {
	// Status doesn't refer to any particular input.
	UNSPECIFIED = 0;

	// Status applies to the breakpoint and is related to its location.
	BREAKPOINT_SOURCE_LOCATION = 3;

	// Status applies to the breakpoint and is related to its condition.
	BREAKPOINT_CONDITION = 4;

	// Status applies to the breakpoint and is related to its expressions.
	BREAKPOINT_EXPRESSION = 7;

	// Status applies to the breakpoint and is related to its age.
	BREAKPOINT_AGE = 8;

	// Status applies to the entire variable.
	VARIABLE_NAME = 5;

	// Status applies to variable value (variable name is valid).
	VARIABLE_VALUE = 6;
	}

	// Distinguishes errors from informational messages.
	bool is_error = 1;

	// Reference to which the message applies.
	Reference refers_to = 2;

	// Status message text.
	FormatMessage description = 3;
	}

	// Represents a location in the source code.
	message SourceLocation {
	// Path to the source file within the source context of the target binary.
	string path = 1;

	// Line inside the file. The first line in the file has the value `1`.
	int32 line = 2;
	}

	// Represents a variable or an argument possibly of a compound object type.
	// Note how the following variables are represented:
	//
	// 1) A simple variable:
	//
	// int x = 5
	//
	// { name: "x", value: "5", type: "int" } // Captured variable
	//
	// 2) A compound object:
	//
	// struct T {
	// int m1;
	// int m2;
	// };
	// T x = { 3, 7 };
	//
	// { // Captured variable
	// name: "x",
	// type: "T",
	// members { name: "m1", value: "3", type: "int" },
	// members { name: "m2", value: "7", type: "int" }
	// }
	//
	// 3) A pointer where the pointee was captured:
	//
	// T x = { 3, 7 };
	// T* p = &x;
	//
	// { // Captured variable
	// name: "p",
	// type: "T*",
	// value: "0x00500500",
	// members { name: "m1", value: "3", type: "int" },
	// members { name: "m2", value: "7", type: "int" }
	// }
	//
	// 4) A pointer where the pointee was not captured:
	//
	// T* p = new T;
	//
	// { // Captured variable
	// name: "p",
	// type: "T*",
	// value: "0x00400400"
	// status { is_error: true, description { format: "unavailable" } }
	// }
	//
	// The status should describe the reason for the missing value,
	// such as `<optimized out>`, `<inaccessible>`, `<pointers limit reached>`.
	//
	// Note that a null pointer should not have members.
	//
	// 5) An unnamed value:
	//
	// int* p = new int(7);
	//
	// { // Captured variable
	// name: "p",
	// value: "0x00500500",
	// type: "int*",
	// members { value: "7", type: "int" } }
	//
	// 6) An unnamed pointer where the pointee was not captured:
	//
	// int* p = new int(7);
	// int** pp = &p;
	//
	// { // Captured variable
	// name: "pp",
	// value: "0x00500500",
	// type: "int**",
	// members {
	// value: "0x00400400",
	// type: "int*"
	// status {
	// is_error: true,
	// description: { format: "unavailable" } }
	// }
	// }
	// }
	//
	// To optimize computation, memory and network traffic, variables that
	// repeat in the output multiple times can be stored once in a shared
	// variable table and be referenced using the `var_table_index` field. The
	// variables stored in the shared table are nameless and are essentially
	// a partition of the complete variable. To reconstruct the complete
	// variable, merge the referencing variable with the referenced variable.
	//
	// When using the shared variable table, the following variables:
	//
	// T x = { 3, 7 };
	// T* p = &x;
	// T& r = x;
	//
	// { name: "x", var_table_index: 3, type: "T" } // Captured variables
	// { name: "p", value "0x00500500", type="T*", var_table_index: 3 }
	// { name: "r", type="T&", var_table_index: 3 }
	//
	// { // Shared variable table entry #3:
	// members { name: "m1", value: "3", type: "int" },
	// members { name: "m2", value: "7", type: "int" }
	// }
	//
	// Note that the pointer address is stored with the referencing variable
	// and not with the referenced variable. This allows the referenced variable
	// to be shared between pointers and references.
	//
	// The type field is optional. The debugger agent may or may not support it.
	message Variable {
	// Name of the variable, if any.
	string name = 1;

	// Simple value of the variable.
	string value = 2;

	// Variable type (e.g. `MyClass`). If the variable is split with
	// `var_table_index`, `type` goes next to `value`. The interpretation of
	// a type is agent specific. It is recommended to include the dynamic type
	// rather than a static type of an object.
	string type = 6;

	// Members contained or pointed to by the variable.
	repeated Variable members = 3;

	// Reference to a variable in the shared variable table. More than
	// one variable can reference the same variable in the table. The
	// `var_table_index` field is an index into `variable_table` in Breakpoint.
	google.protobuf.Int32Value var_table_index = 4;

	// Status associated with the variable. This field will usually stay
	// unset. A status of a single variable only applies to that variable or
	// expression. The rest of breakpoint data still remains valid. Variables
	// might be reported in error state even when breakpoint is not in final
	// state.
	//
	// The message may refer to variable name with `refers_to` set to
	// `VARIABLE_NAME`. Alternatively `refers_to` will be set to `VARIABLE_VALUE`.
	// In either case variable value and members will be unset.
	//
	// Example of error message applied to name: `Invalid expression syntax`.
	//
	// Example of information message applied to value: `Not captured`.
	//
	// Examples of error message applied to value:
	//
	// * `Malformed string`,
	// * `Field f not found in class C`
	// * `Null pointer dereference`
	StatusMessage status = 5;
	}

	// Represents a stack frame context.
	message StackFrame {
	// Demangled function name at the call site.
	string function = 1;

	// Source location of the call site.
	SourceLocation location = 2;

	// Set of arguments passed to this function.
	// Note that this might not be populated for all stack frames.
	repeated Variable arguments = 3;

	// Set of local variables at the stack frame location.
	// Note that this might not be populated for all stack frames.
	repeated Variable locals = 4;
	}

	// Represents the breakpoint specification, status and results.
	message Breakpoint {
	// Actions that can be taken when a breakpoint hits.
	// Agents should reject breakpoints with unsupported or unknown action values.
	enum Action {
	// Capture stack frame and variables and update the breakpoint.
	// The data is only captured once. After that the breakpoint is set
	// in a final state.
	CAPTURE = 0;

	// Log each breakpoint hit. The breakpoint remains active until
	// deleted or expired.
	LOG = 1;
	}

	// Log severity levels.
	enum LogLevel {
	// Information log message.
	INFO = 0;

	// Warning log message.
	WARNING = 1;

	// Error log message.
	ERROR = 2;
	}

	// Breakpoint identifier, unique in the scope of the debuggee.
	string id = 1;

	// Action that the agent should perform when the code at the
	// breakpoint location is hit.
	Action action = 13;

	// Breakpoint source location.
	SourceLocation location = 2;

	// Condition that triggers the breakpoint.
	// The condition is a compound boolean expression composed using expressions
	// in a programming language at the source location.
	string condition = 3;

	// List of read-only expressions to evaluate at the breakpoint location.
	// The expressions are composed using expressions in the programming language
	// at the source location. If the breakpoint action is `LOG`, the evaluated
	// expressions are included in log statements.
	repeated string expressions = 4;

	// Only relevant when action is `LOG`. Defines the message to log when
	// the breakpoint hits. The message may include parameter placeholders `$0`,
	// `$1`, etc. These placeholders are replaced with the evaluated value
	// of the appropriate expression. Expressions not referenced in
	// `log_message_format` are not logged.
	//
	// Example: `Message received, id = $0, count = $1` with
	// `expressions` = `[ message.id, message.count ]`.
	string log_message_format = 14;

	// Indicates the severity of the log. Only relevant when action is `LOG`.
	LogLevel log_level = 15;

	// When true, indicates that this is a final result and the
	// breakpoint state will not change from here on.
	bool is_final_state = 5;

	// Time this breakpoint was created by the server in seconds resolution.
	google.protobuf.Timestamp create_time = 11;

	// Time this breakpoint was finalized as seen by the server in seconds
	// resolution.
	google.protobuf.Timestamp final_time = 12;

	// E-mail address of the user that created this breakpoint
	string user_email = 16;

	// Breakpoint status.
	//
	// The status includes an error flag and a human readable message.
	// This field is usually unset. The message can be either
	// informational or an error message. Regardless, clients should always
	// display the text message back to the user.
	//
	// Error status indicates complete failure of the breakpoint.
	//
	// Example (non-final state): `Still loading symbols...`
	//
	// Examples (final state):
	//
	// * `Invalid line number` referring to location
	// * `Field f not found in class C` referring to condition
	StatusMessage status = 10;

	// The stack at breakpoint time.
	repeated StackFrame stack_frames = 7;

	// Values of evaluated expressions at breakpoint time.
	// The evaluated expressions appear in exactly the same order they
	// are listed in the `expressions` field.
	// The `name` field holds the original expression text, the `value` or
	// `members` field holds the result of the evaluated expression.
	// If the expression cannot be evaluated, the `status` inside the `Variable`
	// will indicate an error and contain the error text.
	repeated Variable evaluated_expressions = 8;

	// The `variable_table` exists to aid with computation, memory and network
	// traffic optimization. It enables storing a variable once and reference
	// it from multiple variables, including variables stored in the
	// `variable_table` itself.
	// For example, the same `this` object, which may appear at many levels of
	// the stack, can have all of its data stored once in this table. The
	// stack frame variables then would hold only a reference to it.
	//
	// The variable `var_table_index` field is an index into this repeated field.
	// The stored objects are nameless and get their name from the referencing
	// variable. The effective variable is a merge of the referencing variable
	// and the referenced variable.
	repeated Variable variable_table = 9;

	// A set of custom breakpoint properties, populated by the agent, to be
	// displayed to the user.
	map<string, string> labels = 17;
	}

	// Represents the application to debug. The application may include one or more
	// replicated processes executing the same code. Each of these processes is
	// attached with a debugger agent, carrying out the debugging commands.
	// The agents attached to the same debuggee are identified by using exactly the
	// same field values when registering.
	message Debuggee {
	// Unique identifier for the debuggee generated by the controller service.
	string id = 1;

	// Project the debuggee is associated with.
	// Use the project number when registering a Google Cloud Platform project.
	string project = 2;

	// Debuggee uniquifier within the project.
	// Any string that identifies the application within the project can be used.
	// Including environment and version or build IDs is recommended.
	string uniquifier = 3;

	// Human readable description of the debuggee.
	// Including a human-readable project name, environment name and version
	// information is recommended.
	string description = 4;

	// If set to `true`, indicates that the debuggee is considered as inactive by
	// the Controller service.
	bool is_inactive = 5;

	// Version ID of the agent release. The version ID is structured as
	// following: `domain/type/vmajor.minor` (for example
	// `google.com/gcp-java/v1.1`).
	string agent_version = 6;

	// If set to `true`, indicates that the agent should disable itself and
	// detach from the debuggee.
	bool is_disabled = 7;

	// Human readable message to be displayed to the user about this debuggee.
	// Absence of this field indicates no status. The message can be either
	// informational or an error status.
	StatusMessage status = 8;

	// References to the locations and revisions of the source code used in the
	// deployed application.
	//
	// NOTE: This field is deprecated. Consumers should use
	// `ext_source_contexts` if it is not empty. Debug agents should populate
	// both this field and `ext_source_contexts`.
	repeated google.devtools.source.v1.SourceContext source_contexts = 9;

	// References to the locations and revisions of the source code used in the
	// deployed application.
	//
	// Contexts describing a remote repo related to the source code
	// have a `category` label of `remote_repo`. Source snapshot source
	// contexts have a `category` of `snapshot`.
	repeated google.devtools.source.v1.ExtendedSourceContext ext_source_contexts = 13;

	// A set of custom debuggee properties, populated by the agent, to be
	// displayed to the user.
	map<string, string> labels = 11;
	}