SPVM::Document::NativeAPI - SPVM Native APIs
SPVM Native APIs is C APIs used in SPVM native method. This document describes the way to define native methods, and shows the all of SPVM Native APIs. If you want to know the list of Native APIs, see List of Native APIs.
Native method can be written by C language or C++, If the code is compatible with C language or C++(for example, CUDA/nvcc), it can be compiled into native method. If you see examples of SPVM Native APIs, see Examples using SPVM Native APIs. This contains the examples of C language, C++ and CUDA/nvcc.
Native Method Declaration is written using Method Descriptor "native" in SPVM module file. SPVM Native Method Declaration ends with a semicolon without Sobroutine Block.
# SPVM/Foo/Bar.spvm class Foo::Bar { native static method sum : int ($num1 : int, $num2 : int); }
SPVM Native Config File must be created for SPVM Native Method. The base name without the extension of native config file must be same as SPVM module file and the extension must be ".config".
# Native configuration file for Foo::Bar module SPVM/Foo/Bar.config
If native configuration file does not exist, an exception occurs.
Native Config File is Perl source code. Native Config File must return properly Builder::Config object, otherwise an exception occurs.
# C99 Config File use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_c99; $config;
# C11 Config File use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_c; $config->set_std('c11'); $config;
# C++ Config File use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_cpp; $config;
# C++11 Config File use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_cpp; $config->set_std('c++11'); $config;
use strict; use warnings; my $config = SPVM::Builder::Config->new; # Compiler and Linker common $config->set_cccdlflags(q(--compiler-options '-fPIC')); # Compiler $config->cc('nvcc'); $config->ccflags(''); $config->ext('cu'); # Linker $config->ld('nvcc'); $config->ldflags('-shared'); $config;
# C99 Config File use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_c99; # Show the compile commands $config->quiet(0); $config;
use strict; use warnings; use SPVM::Builder::Config; my $config = SPVM::Builder::Config->new_c99; # Show the compile commands $config->force(1); $config;
Native Method Definition is written in native source file. Native source file is basically C language source file which extension is ".c". This extension can be changed to ".cpp" for C++ source file, or ".cu" for CUDA source file, etc.
# Native source file for Foo::Bar module SPVM/Foo/Bar.c
The following is natvie source file example written by C language.
#include "spvm_native.h" int32_t SPVM__Foo__Bar__sum(SPVM_ENV* env, SPVM_VALUE* stack) { int32_t num1 = stack[0].ival; int32_t num2 = stakc[1].ival; int32_t total = num1 + num2; stack[0].ival = total; return 0; }
Include "spvm_native.h" at the beginning of the native source file. This header file defines SPVM Native APIs and data structures for Native APIs.
spvm_native.h include the following types.
SPVM_ENV SPVM_VALUE
See List of Native APIs about included SPVM Native APIs.
The return type is "int32_t" type. If the method raises an exception, "1" is returned. If the method is succeed "0" is returned.
Native Method Definition is a simple C language function such as
SPVM__Foo__Bar__sum
The function name starts with "SPVM__".
Followed by class name "Foo__Bar", which is replaced "::" in Foo::Bar.
Followed by "__".
Followed by method name "sum".
If Native Method Name is invalid, a compile error will occur.
There are two arguments, the first argument is "SPVM_ENV* env" which has the information of the execution environment, and the second argument is "SPVM_VALUE* stack" which is used for the argument and return value.
int32_t SPVM__Foo__Bar__sum(SPVM_ENV* env, SPVM_VALUE* stack) { }
In the above sample, it takes two int type arguments of SPVM, calculates the sum, and returns the return value.
Native methods are compiled into a shared libraries. teay are shared libraries (.so) on Unix/Linux, dynamic link libraries (.dll) on Windows or etc corresponding to your os.
The compilation is done when SPVM is compiled. The build directory must exist, otherwise an exception occures.
The default build directory is the "~/.spvm_build" directory in the directory containing the executed Perl script, and can be changed with the environment variable "SPVM_BUILD_DIR".
If you want to use SPVM Native Method from Perl, create a "~/.spvm_build" directory in the directory where the executed Perl script exists.
~/.spvm_build
The generated object files exists under "work/object" under the build directory. The object file name is the name which the extension of the SPVM module name is changed to ".o".
~/.spvm_build/work/object/Foo/Bar.o
The generated shared libraries exists under "work/lib" under the build directory. The name of shared library is the name which the extension of the SPVM module name is changed to ".so", or etc corresponding to your os.
# Unix/Linux ~/.spvm_build/work/object/Foo/Bar.so # Windows ~/.spvm_build/work/object/Foo/Bar.dll
The stack is the second argument of the definition of the Native Method. This is called stack. Stack is used getting arguments and return the value.
SPVM_VALUE is a union type of C language to store SPVM values. You can save integral value, floating point value, object value, and reference value to it.
For example, to get the value of the first argument(0th) of int type, write as follows.
int32_t args0 = stack[0].ival;
For example, to get the value of the second argument(1th) of long type, write as follows.
int64_t args1 = stack[1].lval;
For example, to return a value of double type, write as follows.
stack[0].dval = 0.5;
To get the SPVM byte argument, access the bval field. Assign to the C language int8_t type.
int8_t args0 = stack[0].bval;
To get the short argument of SPVM, access the sval field. Assign it to the C language int16_t type.
int16_t args0 = stack[0].sval;
To get the SPVM int type argument, access the ival field. Assign to the C language int32_t type.
To get the long argument of SPVM, access the lval field. Assign to the C language int64_t type.
int64_t args0 = stack[0].lval;
To get the SPVM float type argument, access the fval field. Assign to float type of C language.
float args0 = stack[0].fval;
To get the SPVM double argument, access the dval field. Assign to the C language double type.
double args0 = stack[0].dval;
To get the SPVM object type argument, access the oval field. Assign it to void* type in C language.
void* args0 = stack[0].oval;
If you get SPVM byte Reference Type argument, use "bref" field. it can be assinged to the value of C language int8_t* type.
int8_t* args0 = stack[0].bref;
If you get SPVM short Reference Type argument, use "sref" field. it can be assinged to the value of C language int16_t* type.
int16_t* args0 = stack[0].sref;
If you get SPVM int Reference Type argument, use "iref" field. it can be assinged to the value of C language int32_t* type.
int32_t* args0 = stack[0].iref;
If you get SPVM long Reference Type argument, use "lref" field. it can be assinged to the value of C language int64_t* type.
int64_t* args0 = stack[0].lref;
If you get SPVM float Reference Type argument, use "fref" field. it can be assinged to the value of C language float* type.
float* args0 = stack[0].fref;
If you get SPVM double Reference Type Argument, use "dref" field. it can be assinged to the value of C language double* type.
double* args0 = stack[0].dref;
In a Native Method, multiple numeric type arguments are assigned to the coresponding multiple arguments.
For example, In the case of the argument values of Complex_2d type, you can get them by the following way.
double args_re = stack[0].dval; double args_im = stack[1].dval;
Note that you cannot access the values by the field name of Complex_2d.
Use bval field of SPVM_VALUE to set a return value which type of SPVM is byte. This is corresponding to int8_t type of C language.
bval
SPVM_VALUE
byte
int8_t
int8_t retval; stack[0].bval = retval;
Use sval field of SPVM_VALUE to set a return value which type of SPVM is short. This is corresponding to int16_t type of C language.
sval
short
int16_t
int16_t retval; stack[0].sval = retval;
Use ival field of SPVM_VALUE to set a return value which type of SPVM is int. This is corresponding to int32_t type of C language.
ival
int
int32_t
int32_t retval; stack[0].ival = retval;
Use lval field of SPVM_VALUE to set a return value which type of SPVM is long. This is corresponding to int64_t type of C language.
lval
long
int64_t
int64_t retval; stack[0].lval = retval;
Use fval field of SPVM_VALUE to set a return value which type of SPVM is float. This is corresponding to float type of C language.
fval
float
float retval; stack[0].fval = retval;
Use dval field of SPVM_VALUE to set a return value which type of SPVM is double. This is corresponding to double type of C language.
dval
double
double retval; stack[0].dval = retval;
Use oval field of SPVM_VALUE to set a return value which type of SPVM is object. This is corresponding to void* type of C language.
oval
void*
void* retval; stack[0].oval = retval;
If you set multiple numeric return value in native method, set multiple return values.
For example, in the case of Complex_2d, do the following.
double retval_x; double retval_y; stack[0].dval = retval_x; stack[1].dval = retval_y;
If you want to call a method, you get a method id using get_class_method_id or get_instance_method_id.
get_class_method_id get a method id of a class method.
get_instance_method_id get a method id of a instance method.
// Get method id of class method int32_t method_id = env->get_class_method_id(env, "Foo", "sum", "int(int,int)"); // Get method id of instance method int32_t method_id = env->get_instance_method_id(env, object, "sum", "int(int,int)");
If method_id is less than 0, it means that the method was not found. It is safe to handle exceptions as follows.
if (method_id < 0) { return env->die(env, "Can't find method id", "Foo/Bar.c", __LINE__); }
Set the SPVM method argument to stack before calling the method.
stack[0].ival = 1; stack[0].ival = 2;
To call a SPVM method, use the <a href="#native-api-native-sub-api-call_spvm_method">call_spvm_method</a> function.
int32_t exception_flag = env->call_spvm_method(env, method_id, stack);
Nonzero if the method raised an exception, 0 if no exception occurred.
The return value of the method is stored in the first element of the stack.
int32_t total = stack[0].ival;
Native method are entirely enclosed in scope.
Objects added to the mortal stack will automatically have their reference count decremented by 1 when the Native Method ends. When the reference count reaches 0, it is released.
Use push_mortal to add objects to the mortal stack.
env->push_mortal(env, object);
Native APIs that normally create an object such as "new_object" will add the automatically created object to the mortal stack so you don't need to use this.
Use "enter_scope" to create a scope. The return value is the ID of that scope.
int32_t scope_id = env->enter_scope (env);
Use "leave_scope" to leave the scope. For the argument, it is necessary to specify the scope ID obtained in "enter_scope".
env->leave_scope(env, scope_id);
Use "remove_mortal" to remove the object from the mortal stack. For the argument, specify the scope ID obtained by "enter_scope" and the object you want to remove. The object is removed from the mortal stack and the reference count is automatically decremented by 1. When the reference count reaches 0, it is released.
env->remove_mortal(env, scope_id, object);
Information about the mortal stack is stored in env.
In the Native Method, it is the return value that indicates whether an exception has occurred.
return 0; return 1;
If no exception occurs, "0" is returned. This is defined as "0".
If an exception occurs, "1" is returned. It is defined as a value other than "0".
If you want to set the exception message yourself, you can create an exception message with "new_string_nolen" and set it with "set_exception".
env->set_exception(env, env->new_string_nolen(env, "Exception occur"); return 1;
If no exception message is set, a default exception message will be set.
Usually, die is defined to make it easier to use, so it is better to use this.
return env->die("Error. Values must be %d and %d", 3, 5, "Foo/Bar.c", __LINE__);
die can be used in the same way as the C language sprintf function. Be sure to include this file name in the second from the end, and the line number in the last argument. If the message exceeds 255 bytes, the excess is truncated.
The exception is stored in env.
There is a type called pointer type in SPVM, but I will explain how to use it.
The pointer type definition specifies the pointer_t descriptor in the SPVM class definition. Pointer types cannot have field definitions. This example describes how to use the C standard "struct tm" as a pointer type.
# SPVM/MyTimeInfo.spvm class MyTimeInfo : pointer_t { # Constructor native static method new : MyTimeInfo (); # Get second native method sec : int (); # Destructor native method DESTROY : (); }
It defines a new constructor, a method that takes seconds information called sec, and a destructor called DESTROY. These are Native Method.
Next is the definition on the C language side.
# SPVM/MyTimeInfo.c int32_t SPVM__SPVM__MyTimeInfo__new(SPVM_ENV* env, SPVM_VALUE* stack) { // Alloc strcut tm void* tm_ptr = env->alloc_memory_block_zero (sizeof (struct tm)); // Create strcut tm instance void* tm_obj = env->new_pointer(env, "MyTimeInfo", tm_ptr); stack[0].oval = tm_obj; return 0; } int32_t SPVM__SPVM__MyTimeInfo__sec(SPVM_ENV* env, SPVM_VALUE* stack) { void* tm_obj = stack[0].oval; strcut tm* tm_ptr = (struct tm*) env->get_pointer(env, tm_obj); stack[0].ival = tm_ptr-> tm_sec; return 0; } int32_t SPVM__SPVM__MyTimeInfo__DESTROY(SPVM_ENV* env, SPVM_VALUE* stack) { void* tm_obj = stack[0].oval; strcut tm* tm_ptr = (struct tm*) env->get_pointer(env, tm_obj); env->free_memory_block (tm_ptr); return 0; }
In the constructor new, the memory of "struct tm" is first allocated by the alloc_memory_block_zero function. This is a function that reserves one memory block in SPVM. Similar to malloc, this function increments the memory block count by one, making it easier to spot memory leaks.
// Alloc strcut tm void* tm_ptr = env->alloc_memory_block_zero (sizeof (struct tm));
Next, use the new_pointer function to create a new pointer type object with MyTimeInfo associated with it in the allocated memory.
// Create strcut tm instance void* tm_obj = env->new_pointer(env, "MyTimeInfo", tm_ptr);
If you return this as a return value, the constructor is complete.
stack[0].ival = tm_ptr-> tm_sec; return 0;
Next, let's get the value of tm_sec. sec method. The get_pointer function can be used to get a pointer to the memory allocated as a "struct tm" from a pointer type object.
void* tm_obj = stack[0].oval; strcut tm* tm_ptr = (struct tm*) env->get_pointer(env, tm_obj); stack[0].ival = tm_ptr-> tm_sec;
The last is the destructor. Be sure to define a destructor, as the allocated memory will not be released automatically.
int32_t SPVM__SPVM__MyTimeInfo__DESTROY(SPVM_ENV* env, SPVM_VALUE* stack) { void* tm_obj = stack[0].oval; strcut tm* tm_ptr = (struct tm*) env->get_pointer(env, tm_obj); env->free_memory_block (tm_ptr); return 0; }
Execute the free_memory_block function to free the memory. Be sure to free the memory allocated by alloc_memory_block_zero with the free_memory_block function. Releases the memory and decrements the memory block count by one.
Native API can be called from "SPVM_ENV* env" passed as an argument. Note that you have to pass env as the first argument.
int32_t basic_type_id = env->get_basic_type_id(env, "Int");
void* class_vars_heap;
the pointer to the storage area of the class variables. This is used internally.
void* object_header_byte_size;
The byte size of the object's header. This is used internally.
void* object_weaken_backref_head_offset;
Offset to a pointer to the back reference of the weak reference in the object structure. This is used internally.
void* object_ref_count_offset;
Reference count offset in the object structure. This is used internally.
void* object_basic_type_id_offset;
Offset of basic type ID in object structure. This is used internally.
void* object_type_dimension_offset;
Offset of type dimension in object structure. This is used internally.
void* object_type_category_offset;
Offset of runtime type category in object structure. This is used internally.
void* object_flag_offset;
Offset of flag in object structure. This is used internally.
void* object_length_offset;
The length offset in the object structure. This is used internally.
void* byte_object_basic_type_id;
Basic type ID of Byte type. This is used internally.
void* short_object_basic_type_id;
ID of the base type of Short type. This is used internally.
void* int_object_basic_type_id;
ID of the base type of Int type. This is used internally.
void* long_object_basic_type_id;
ID of the base type of Long type. This is used internally.
void* float_object_basic_type_id;
ID of the base type of Float type. This is used internally.
void* double_object_basic_type_id;
ID of the base type of Double type. This is used internally.
void* compiler;
A pointer to the SPVM compiler. This is used internally.
void* exception_object;
Exception object. This is used internally.
void* native_mortal_stack;
Mortal stack used for native calls. This is used internally.
void* native_mortal_stack_top;
The top position of the mortal stack used for native calls. This is used internally.
void* native_mortal_stack_capacity;
The amount of mortal stack used for native calls. This is used internally.
int32_t (*get_basic_type_id)(SPVM_ENV* env, const char* basic_type_name);
Get the ID of the base type given the name of the base type. If it does not exist, a value less than 0 is returned.
Example:
int32_t (*get_field_id)(SPVM_ENV* env, const char* class_name, const char* field_name, const char* signature);
Get the ID of the field given the class name, field name, and signature. If the field does not exist, a value less than 0 is returned.
The signature is the same as the field type name.
int32_t field_id = env->get_field_id(env, "Foo", "x", "int");
int32_t (*get_field_offset)(SPVM_ENV* env, int32_t field_id);
Gets the offset of the field given the field ID. The field ID must be a valid field ID obtained with the field_id function.
int32_t (*get_class_var_id)(SPVM_ENV* env, const char* class_name, const char* class_var_name, const char* signature);
Get the class variable ID given the class name, class variable name and signature. If the class variable does not exist, a value less than 0 is returned.
The signature is the same as the class variable type name.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "int");
int32_t (*get_class_method_id)(SPVM_ENV* env, const char* class_name, const char* method_name, const char* signature);
Get a class method ID by the class name, the method name, and the method signature. If the class method does not exists, a negative value is returned.
This ID is used by "call_class_method".
The method signature has the following format.
ReturnValueType(ArgumentType1,ArgumentType2,...)
int32_t method_id = env->get_class_method_id(env, "Foo", "get", "int(long,string)");
int32_t (*get_instance_method_id)(SPVM_ENV* env, void* object, const char* method_name, const char* signature);
Get a instance method ID by the object, the method name, and the method signatre. If the instance method does not exist, a negative value is returned.
This ID is used by "call_instance_method".
The method signature has the following format,
int32_t method_id = env->get_instance_method_id(env, object, "get", "int(long,string)");
void* (*new_object_raw)(SPVM_ENV* env, int32_t basic_type_id);
Create a new object with a basic type ID. The basic type ID must be the correct base type ID return by get_basic_type_id function.
get_basic_type_id
void* (*new_object)(SPVM_ENV* env, int32_t basic_type_id);
Do the same as new_object_raw, and add the created object to the mortal stack of the environment. Use this function in normal use instead of new_object_raw.
new_object_raw
int32_t basic_type_id = env->get_basic_type_id(env, "Int"); void* object = env->new_object(env, basic_type_id);
void* (*new_byte_array_raw)(SPVM_ENV* env, int32_t length);
Create a new byte[] type array by specifying the length.
void* (*new_byte_array)(SPVM_ENV* env, int32_t length);
Do the same as new_byte_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_byte_array_raw.
new_byte_array_raw
void* byte_array = env->new_byte_array(env, 100);
void* (*new_short_array_raw)(SPVM_ENV* env, int32_t length);
Create a new short[] type array by specifying the length.
void* (*new_short_array)(SPVM_ENV* env, int32_t length);
Do the same as new_short_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_short_array_raw.
new_short_array_raw
void* short_array = env->new_short_array(env, 100);
void* (*new_int_array_raw)(SPVM_ENV* env, int32_t length);
Create a new int[] type array by specifying the length.
void* (*new_int_array)(SPVM_ENV* env, int32_t length);
Do the same as new_int_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_int_array_raw.
new_int_array_raw
void* int_array = env->new_int_array(env, 100);
void* (*new_long_array_raw)(SPVM_ENV* env, int32_t length);
Create a new long[] type array by specifying the length.
void* (*new_long_array)(SPVM_ENV* env, int32_t length);
Do the same as new_long_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_long_array_raw.
new_long_array_raw
void* long_array = env->new_long_array(env, 100);
void* (*new_float_array_raw)(SPVM_ENV* env, int32_t length);
Create a new float[] type array by specifying the length.
void* (*new_float_array)(SPVM_ENV* env, int32_t length);
Do the same as new_float_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_float_array_raw.
new_float_array_raw
void* float_array = env->new_float_array(env, 100);
void* (*new_double_array_raw)(SPVM_ENV* env, int32_t length);
Create a new double[] type array by specifying the length.
void* (*new_double_array)(SPVM_ENV* env, int32_t length);
Do the same as new_double_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_double_array_raw.
new_double_array_raw
void* double_array = env->new_double_array(env, 100);
void* (*new_object_array_raw)(SPVM_ENV* env, int32_t basic_type_id, int32_t length);
Create a new object type array by specifying the basic type ID and the array length. The basic type ID must be the correct basic type ID got by get_basic_type_id function.
void* (*new_object_array)(SPVM_ENV* env, int32_t basic_type_id, int32_t length);
Do the same as new_object_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_object_array_raw.
new_object_array_raw
int32_t basic_type_id = env->get_basic_type_id(env, "Int"); void* object_array = env->new_object_array(env, basic_type_id, 100);
void* (*new_muldim_array_raw)(SPVM_ENV* env, int32_t basic_type_id, int32_t element_dimension, int32_t length);
Create a new multi dimension array by specifying the basic type ID, the type dimension of the element, and the array length. The basic type ID must be the correct basic type ID got bu get_basic_type_id function. the type dimension of the element must be less than or equals to 255.
Do the same as new_muldim_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_muldim_array_raw.
new_muldim_array_raw
// new Int[][][100] int32_t basic_type_id = env->get_basic_type_id(env, "Int"); void* multi_array = env->new_muldim_array(env, basic_type_id, 2, 100);
void* (*new_mulnum_array_raw)(SPVM_ENV* env, int32_t basic_type_id, int32_t length);
Create a new multi-numeric array by specifying the basic type ID and the array length. The basic type ID must be the correct basic type ID got by basic_type_id function.
basic_type_id
void* (*new_mulnum_array)(SPVM_ENV* env, int32_t basic_type_id, int32_t length);
Do the same as new_mulnum_array_raw, and add the created array to the mortal stack of the environment. Use this function in normal use instead of new_mulnum_array_raw.
new_mulnum_array_raw
int32_t basic_type_id = env->get_basic_type_id(env, "Complex_2d"); void* value_array = env->new_mulnum_array(env, basic_type_id, 100);
void* (*new_string_nolen_raw)(SPVM_ENV* env, const char* bytes);
Create a new string object by specifying C language char* type value. this value must end with "\0".
void* (*new_string_nolen)(SPVM_ENV* env, const char* bytes);
Do the same as new_string_nolen_raw, and add the created string object to the mortal stack of the environment. Use this function in normal use instead of new_string_nolen_raw.
new_string_nolen_raw
void* str_obj = env->new_string_nolen(env, "Hello World");
void* (*new_string_raw)(SPVM_ENV* env, const char* bytes, int32_t length);
Create a new string object by specifying C language char* type value and the length.
void* (*new_string)(SPVM_ENV* env, const char* bytes, int32_t length);
Do the same as new_string_raw, and add the created string object to the mortal stack of the environment. Use this function in normal use instead of new_string_raw.
new_string_raw
void* str_obj = env->new_string(env, "Hello \0World", 11);
void* (*new_pointer_raw)(SPVM_ENV* env, int32_t basic_type_id, void* pointer);
Create a pointer type object by specifying a basic type ID and a C language pointer. The basic type ID must be the correct basic type ID got by get_basic_type_id function.
void* (*new_pointer)(SPVM_ENV* env, int32_t basic_type_id, void* pointer);
Do the same as new_pointer_raw, and add the created string object to the mortal stack of the environment. Use this function in normal use instead of new_pointer_raw.
new_pointer_raw
int32_t basic_type_id = env->get_basic_type_id(env, "MyTime"); void* pointer = malloc(sizeof (struct tm)); void* pointer_obj = env->new_pointer(env, basic_type_id, pointer);
void* (*concat_raw)(SPVM_ENV* env, void* string1, void* string2);
Concat two strings.
void* (*concat)(SPVM_ENV* env, void* string1, void* string2);
Do the same as concat_raw, and add the created string object to the mortal stack of the environment. Use this function in normal use instead of concat_raw.
concat_raw
void* (*new_stack_trace_raw)(SPVM_ENV* env, void* exception, const char* class_name, const char* method_name, const char* file, int32_t line);
If you specify a byte[] type exception message and a class name, method name, file name and line number, the character string of the class name, method name, file name and line number is added to the end of the byte[] type exception message. The added character string will be returned.
This function does not add objects to the mortal stack, use new_stack_trace to avoid memory leaks for normal use.
void* (*new_stack_trace)(SPVM_ENV* env, void* exception, const char* class_name, const char* method_name, const char* file, int32_t line);
When a byte[] type exception message and a class name, method name, file name and line number are specified, the string of the class name, method name, file name and line number is added to the end of the string type exception message. Returns a new string type object. Add the newly created object to the mortal stack.
int32_t (*length)(SPVM_ENV*, void* array);
If you specify an array, the length of the array is returned.
int32_t length = env->length(env, array);
int8_t* (*get_elems_byte)(SPVM_ENV* env, void* array);
If you specify a byte[] type array, the pointer at the beginning of the internally stored C language int8_t[] type array is returned.
int8_t* values = env->get_elems_byte(env, array); values[3] = 5;
int16_t* (*get_elems_short)(SPVM_ENV* env, void* array);
If a short[] type array is specified, the pointer at the beginning of the internally stored C language int16_t[] type array is returned.
int16_t* values = env->get_elems_short(env, array); values[3] = 5;
int32_t* (*get_elems_int)(SPVM_ENV* env, void* array);
When an int[] type array is specified, the pointer at the beginning of the internally stored C language int32_t[] type array is returned.
int32_t* values = env->get_elems_int(env, array); values[3] = 5;
int64_t* (*get_elems_long)(SPVM_ENV* env, void* array);
When a long[] type array is specified, the pointer at the beginning of the internally stored C language int64_t[] type array is returned.
int64_t* values = env->get_elems_long(env, array); values[3] = 5;
float* (*get_elems_float)(SPVM_ENV* env, void* array);
When a float[] type array is specified, the pointer at the beginning of the C language float[] type array internally held is returned.
float* values = env->get_elems_float(env, array); values[3] = 1.5f;
double* (*get_elems_double)(SPVM_ENV* env, void* array);
If a double[] type array is specified, the pointer at the beginning of the internally stored C double[] type array is returned.
double* values = env->get_elems_double(env, array); values[3] = 1.5;
void* (*get_elem_object)(SPVM_ENV* env, void* array, int32_t index);
Gets an object of an element given an array of object types and a methodscript. If the element is a weak reference, the weak reference is removed.
void* object = env->get_elem_object(env, array, 3);
void (*set_elem_object)(SPVM_ENV* env, void* array, int32_t index, void* value);
If you specify an array of object type and methodscript and element objects, the element object is assigned to the corresponding methodscript position. If the element's object has a weak reference, the weak reference is removed. The reference count of the originally assigned object is decremented by 1.
env->get_elem_object(env, array, 3, object);
int8_t (*get_field_byte)(SPVM_ENV* env, void* object, int32_t field_id);
If an object and field ID are specified, the byte field value will be returned as a C language int8_t type value. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "byte"); int8_t field_value = env->get_field_byte(env, object, field_id);
int16_t (*get_field_short)(SPVM_ENV* env, void* object, int32_t field_id);
If you specify the object and field ID, the value of the short type field will be returned as the int16_t type value of C language. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "short"); int16_t field_value = env->get_field_short(env, object, field_id);
int32_t (*get_field_int)(SPVM_ENV* env, void* object, int32_t field_id);
If an object and a field ID are specified, the value of the int type field will be returned as a C language int32_t type value. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "int"); int32_t field_value = env->get_field_int(env, object, field_id);
int64_t (*get_field_long)(SPVM_ENV* env, void* object, int32_t field_id);
If you specify the object and field ID, the value of the long type field will be returned as the value of int64_t type of C language. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "long"); int64_t field_value = env->get_field_long(env, object, field_id);
float (*get_field_float)(SPVM_ENV* env, void* object, int32_t field_id);
If you specify the object and field ID, the value of the float type field will be returned as a C language float type value. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "float"); float field_value = env->get_field_float(env, object, field_id);
double (*get_field_double)(SPVM_ENV* env, void* object, int32_t field_id);
If you specify the object and field ID, the value of the double type field will be returned as a double type value in C language. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "double"); double field_value = env->get_field_double(env, object, field_id);
void* (*get_field_object)(SPVM_ENV* env, void* object, int32_t field_id);
If you specify the object and field ID, the value of the object type field is returned as a void* type value in C language. The field ID must be a valid field ID obtained with the field_id function. If the field is a weak reference, it will be removed.
int32_t field_id = env->get_field_id(env, "Foo", "x", "Int"); void* field_value = env->get_field_object(env, object, field_id);
void (*set_field_byte)(SPVM_ENV* env, void* object, int32_t field_id, int8_t value);
If you specify the object and field ID and the value of the field, the value is set to the byte type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "byte"); int8_t field_value = 5; env->set_field_byte(env, object, field_id, field_value);
void (*set_field_short)(SPVM_ENV* env, void* object, int32_t field_id, int16_t value);
If you specify the object and field ID and the value of the field, the value is set to the short type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "short"); int16_t field_value = 5; env->set_field_short(env, object, field_id, field_value);
void (*set_field_int)(SPVM_ENV* env, void* object, int32_t field_id, int32_t value);
If you specify the object and field ID and the value of the field, the value is set to the int type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "int"); int32_t field_value = 5; env->set_field_int(env, object, field_id, field_value);
void (*set_field_long)(SPVM_ENV* env, void* object, int32_t field_id, int64_t value);
If you specify the object and field ID and the value of the field, the value is set to the long type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "long"); int64_t field_value = 5; env->set_field_long(env, object, field_id, field_value);
void (*set_field_float)(SPVM_ENV* env, void* object, int32_t field_id, float value);
If you specify the object and field ID and the value of the field, the value is set to the float type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "float"); float field_value = 1.5f; env->set_field_float(env, object, field_id, field_value);
void (*set_field_double)(SPVM_ENV* env, void* object, int32_t field_id, double value);
If you specify the object and field ID and the value of the field, the value is set to the double type field. The field ID must be a valid field ID obtained with the field_id function.
int32_t field_id = env->get_field_id(env, "Foo", "x", "double"); double field_value = 1.55; env->set_field_double(env, object, field_id, field_value);
void (*set_field_object)(SPVM_ENV* env, void* object, int32_t field_id, void* value);
Object and field Specify the ID and the value of the field and set the value to the object type field. The field ID must be a valid field ID obtained with the field_id function. After setting, the reference count is incremented by 1. The original value has the reference count decremented by 1.
int32_t field_id = env->get_field_id(env, "Foo", "x", "Int"); int32_t basic_type_id = env->get_basic_type_id(env, "Int"); void* object = env->new_object(env, basic_type_id); env->set_field_object(env, object, field_id, object);
int8_t (*get_class_var_byte)(SPVM_ENV* env, int32_t pkgvar_id);
If an object and a class variable ID are specified, the value of the byte type class variable is returned as a C language int8_t type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "byte"); int8_t pkgvar_value = env->get_class_var_byte(env, object, pkgvar_id);
int16_t (*get_class_var_short)(SPVM_ENV* env, int32_t pkgvar_id);
If an object and a class variable ID are specified, the value of the short type class variable will be returned as a C language int16_t type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "short"); int16_t pkgvar_value = env->get_class_var_short(env, object, pkgvar_id);
int32_t (*get_class_var_int)(SPVM_ENV* env, int32_t pkgvar_id);
If an object and a class variable ID are specified, the value of the int type class variable will be returned as a C language int32_t type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "int"); int32_t pkgvar_value = env->get_class_var_int(env, object, pkgvar_id);
int64_t (*get_class_var_long)(SPVM_ENV* env, int32_t pkgvar_id);
If an object and a class variable ID are specified, the value of the long type class variable will be returned as a C language int64_t type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "long"); int64_t pkgvar_value = env->get_class_var_long(env, object, pkgvar_id);
float (*get_class_var_float)(SPVM_ENV* env, int32_t pkgvar_id);
If an object and a class variable ID are specified, the value of the float type class variable will be returned as a C language float type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "float"); float pkgvar_value = env->get_class_var_float(env, object, pkgvar_id);
double (*get_class_var_double)(SPVM_ENV* env, int32_t pkgvar_id);
If you specify an object and a class variable ID, the value of the double type class variable is returned as a C type double type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "double"); double pkgvar_value = env->get_class_var_double(env, object, pkgvar_id);
void* (*get_class_var_object)(SPVM_ENV* env, int32_t pkgvar_id);
When an object and a class variable ID are specified, the value of the object type class variable is returned as a C language void* type value. The class variable ID must be a valid class variable ID obtained with the field_id function.
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "Int"); void* pkgvar_value = env->get_class_var_byte(env, object, pkgvar_id);
void (*set_class_var_byte)(SPVM_ENV* env, int32_t pkgvar_id, int8_t value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "byte"); int8_t pkgvar_value = 5; env->set_class_var_byte(env, pkgvar_id, pkgvar_value);
void (*set_class_var_short)(SPVM_ENV* env, int32_t pkgvar_id, int16_t value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "short"); int16_t pkgvar_value = 5; env->set_class_var_short(env, pkgvar_id, pkgvar_value);
void (*set_class_var_int)(SPVM_ENV* env, int32_t pkgvar_id, int32_t value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "int"); int32_t pkgvar_value = 5; env->set_class_var_int(env, pkgvar_id, pkgvar_value);
void (*set_class_var_long)(SPVM_ENV* env, int32_t pkgvar_id, int64_t value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "long"); int64_t pkgvar_value = 5; env->set_class_var_long(env, pkgvar_id, pkgvar_value);
void (*set_class_var_float)(SPVM_ENV* env, int32_t pkgvar_id, float value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "float"); float pkgvar_value = 5; env->set_class_var_float(env, pkgvar_id, pkgvar_value);
void (*set_class_var_double)(SPVM_ENV* env, int32_t pkgvar_id, double value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "double"); double pkgvar_value = 5; env->set_class_var_double(env, pkgvar_id, pkgvar_value);
void (*set_class_var_object)(SPVM_ENV* env, int32_t pkgvar_id, void* value);
int32_t pkgvar_id = env->get_class_var_id(env, "Foo", "$VAR", "Int"); int32_t basic_type_id = env->get_basic_type_id(env, "Int"); void* object = env->new_object(env, basic_type_id); env->set_class_var_object(env, pkgvar_id, pkgvar_value);
void* (*get_pointer)(SPVM_ENV* env, void* pointer_object);
Specify a pointer type object and return the C language pointer stored inside the object.
strcut tm* tm_ptr = (struct tm*) env->get_pointer(env, tm_obj);
void (*set_pointer)(SPVM_ENV* env, void* pointer_object, void* pointer);
If you specify a pointer type object and a C language pointer, the C language pointer is saved in the internal data of the pointer type object.
int32_t (*call_spvm_method)(SPVM_ENV* env, int32_t method_id, SPVM_VALUE* args);
Call a method by specifying the method ID and argument. If an exception occurs in the method, The return value is 1. If not, return 0.
The return value of the method is set to args[0].
void* (*get_exception)(SPVM_ENV* env);
Get a exception message which type is byte[].
void (*set_exception)(SPVM_ENV* env, void* exception);
Set a exception message which type is byte[].
int32_t (*get_ref_count)(SPVM_ENV* env, void* object);
Get the refernce count of the object.
void (*inc_ref_count)(SPVM_ENV* env, void* object);
Specifying an object increments the reference count of the object.
Use this method only if you have a specific reason to use it. Normally, the reference count is managed automatically.
void (*dec_ref_count)(SPVM_ENV* env, void* object);
Specifying an object decrements the object's reference count by 1. When the reference count reaches 0, the object is released.
int32_t (*enter_scope)(SPVM_ENV* env);
Create a new scope and return the scope ID.
int32_t (*push_mortal)(SPVM_ENV* env, void* object);
Add an object to the mortal stack.
If this method succeed, return 0.
If this method don't alloc memory for new mortal information, return 1.
void (*leave_scope)(SPVM_ENV* env, int32_t scope_id);
Specify a scope ID to exit that scope and decrement the object's reference count stored in the mortal stack. Objects with a reference count of 0 are released. The scope ID must be the ID obtained by the enter_scope function.
int32_t (*remove_mortal)(SPVM_ENV* env, int32_t scope_id, void* remove_object);
Given a scope ID and an object, delete the specified object from the mortal stack.
int32_t (*is_type)(SPVM_ENV* env, void* object, int32_t basic_type_id, int32_t type_dimension);
Given an object and a base type ID and a type dimension, returns a nonzero value if the object matches both the base type ID and the type dimension, and 0 otherwise.
int32_t (*has_callback)(SPVM_ENV* env, void* object, int32_t callback_basic_type_id);
Given a base type id for the object and the callback type, returns a non-zero value if the object conforms to the callback type, and zero otherwise.
int32_t (*get_object_basic_type_id)(SPVM_ENV* env, void* object);
Gets the base type ID of the object.
int32_t (*get_object_type_dimension)(SPVM_ENV* env, void* object);
Gets the dimension of the type of object.
int32_t (*weaken)(SPVM_ENV* env, void** object_address);
Create weak reference to the object which is specified by object address.
The reference count of the object is decrimented by 1 and weaken flag is added to the object address.
If the reference count is 1, "dec_ref_count" is called to the object.
If object_address is NULL, this method do nothing.
If the object is already weaken, this method do nothing.
This method allocate memory internally to add the back reference from the object to the object address.
This method success return 0.
If failing memory allocation of back reference, return 1.
int32_t (*isweak()SPVM_ENV* env, void** object);
Given the address of an object, returns non-zero if the object is a weak reference, 0 otherwise.
void (*unweaken)(SPVM_ENV* env, void** object_address);
Specifying the address of the object releases the weak reference to the object.
void* (*alloc_memory_block_zero)(SPVM_ENV* env, int64_t byte_size);
If you specify the size in bytes, the memory block is allocated and the pointer of the allocated memory block is returned. If fail to alloc memory, return NULL. If success, all bits in the memory block are initialized with 0 and the memory block count (memory_blocks_count)is incremented by 1.
void (*free_memory_block)(SPVM_ENV* env, void* block);
If block is not NULL, free the memory and memory blocks count(memory_blocks_count) is decremented by 1.
int32_t (*get_memory_blocks_count)(SPVM_ENV* env);
Returns the current number of memory blocks.
The memory block is increased by 1 when an object is created, when the alloc_memory_block_zero function is called, and when a back reference is added by the weaken function.
void* (*get_type_name_raw)(SPVM_ENV* env, void* object);
If you specify an object, a new byte[] type object that stores the type name is returned.
This function does not add objects to the mortal stack, so use type_name for normal use to avoid memory leaks.
void* (*get_type_name)(SPVM_ENV* env, void* object);
If you specify an object, a new byte[] type object that stores the type name is returned. Add the newly created object to the mortal stack.
SPVM_ENV* (*new_env)(SPVM_ENV* env);
Create a new execution environment based on the current execution environment.
Create a new SPVM runtime environment.
The exception object and mortal stack information will be initialized.
Share the class variables with the original execution environment.
The number of memory blocks is shared with the original execution environment.
If thie method can't allocate memory for SPVM runtime environment, return NULL.
void (*free_env)(SPVM_ENV* env);
Release the execution environment.
void* memory_blocks_count;
Memory blocks count. This is used internally.
const char* (*get_chars)(SPVM_ENV* env, void* string_object);
Get characters pointer in the string object.
const char* bytes = env->get_chars(env, string_object);
int32_t (*die)(SPVM_ENV* env, const char* message, ...);
Create a sprintf formatted message with file name and line number and set it to the exception.
sprintf
Last two arguments are file name and line number.
Return value is always 1;
return env->die(env, "Value must be %d", 3, __FILE__, __LINE__);
void* (*new_object_by_name)(SPVM_ENV* env, const char* class_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as new_object function, but you can specify class name directry.
new_object
If function is succeeded, exception_flag is set to 0. If a exception occurs, exception_flag is set to 1.
exception_flag
int32_t e; void* minimal = env->new_object_by_name(env, "TestCase::Minimal", &e, __FILE__, __LINE__); if (e) { return e; }
void* (*new_pointer_by_name)(SPVM_ENV* env, const char* class_name, void* pointer, int32_t* exception_flag, const char* file, int32_t line);
This is same as new_pointer function, but you can specify class name directry.
new_pointer
int32_t e; void* minimal = env->new_pointer_by_name(env, "TestCase::Pointer", pointer, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_byte_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int8_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_byte function, but you can specify class name and field name directry.
set_field_byte
int32_t e; env->set_field_byte_by_name(env, object, "TestCase::Simple", "byte_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_short_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int16_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_short function, but you can specify class name and field name directry.
set_field_short
int32_t e; env->set_field_short_by_name(env, object, "TestCase::Simple", "short_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_int_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_int function, but you can specify class name and field name directry.
set_field_int
int32_t e; env->set_field_int_by_name(env, object, "TestCase::Simple", "int_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_long_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int64_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_long function, but you can specify class name and field name directry.
set_field_long
int32_t e; env->set_field_long_by_name(env, object, "TestCase::Simple", "long_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_float_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, float value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_float function, but you can specify class name and field name directry.
set_field_float
int32_t e; env->set_field_float_by_name(env, object, "TestCase::Simple", "float_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_double_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, double value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_double function, but you can specify class name and field name directry.
set_field_double
int32_t e; env->set_field_double_by_name(env, object, "TestCase::Simple", "double_value", 13, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_field_object_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, const char* signature, void* value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_field_object function, but you can specify class name and field name directry.
set_field_object
int32_t e; env->set_field_object_by_name(env, object_simple, "TestCase::Simple", "object_value", "TestCase::Minimal", object_minimal, &e, __FILE__, __LINE__); if (e) { return e; }
int8_t (*get_field_byte_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_byte function, but you can specify class name and field name directry.
get_field_byte
If function is succeeded, exception_flag is get to 0. If a exception occurs, exception_flag is get to 1.
int32_t e; int8_t byte_value = env->get_field_byte_by_name(env, object, "TestCase::Simple", "byte_value", &e, __FILE__, __LINE__); if (e) { return e; }
int16_t (*get_field_short_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_short function, but you can specify class name and field name directry.
get_field_short
int32_t e; int8_t short_value = env->get_field_short_by_name(env, object, "TestCase::Simple", "short_value", &e, __FILE__, __LINE__); if (e) { return e; }
int32_t (*get_field_int_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_int function, but you can specify class name and field name directry.
get_field_int
int32_t e; int8_t int_value = env->get_field_int_by_name(env, object, "TestCase::Simple", "int_value", &e, __FILE__, __LINE__); if (e) { return e; }
int64_t (*get_field_long_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_long function, but you can specify class name and field name directry.
get_field_long
int32_t e; int8_t long_value = env->get_field_long_by_name(env, object, "TestCase::Simple", "long_value", &e, __FILE__, __LINE__); if (e) { return e; }
float (*get_field_float_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_float function, but you can specify class name and field name directry.
get_field_float
int32_t e; int8_t float_value = env->get_field_float_by_name(env, object, "TestCase::Simple", "float_value", &e, __FILE__, __LINE__); if (e) { return e; }
double (*get_field_double_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_double function, but you can specify class name and field name directry.
get_field_double
int32_t e; int8_t double_value = env->get_field_double_by_name(env, object, "TestCase::Simple", "double_value", &e, __FILE__, __LINE__); if (e) { return e; }
void* (*get_field_object_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, const char* signature, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_field_object function, but you can specify class name and field name directry.
get_field_object
int32_t e; void* object_minimal = env->get_field_object_by_name(env, object_simple, "TestCase::Simple", "object_value", "TestCase::Minimal", &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_byte_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int8_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_byte function, but you can specify the class name directry.
set_class_var_byte
int32_t e; env->set_class_var_byte_by_name(env, "TestCase::NativeAPI", "$BYTE_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_short_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int16_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_short function, but you can specify the class name directry.
set_class_var_short
int32_t e; env->set_class_var_short_by_name(env, "TestCase::NativeAPI", "$SHORT_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_int_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_int function, but you can specify the class name directry.
set_class_var_int
int32_t e; env->set_class_var_int_by_name(env, "TestCase::NativeAPI", "$INT_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_long_by_name)(SPVM_ENV* env const char* class_name, const char* class_var_name, int64_t value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_long function, but you can specify the class name directry.
set_class_var_long
int32_t e; env->set_class_var_long_by_name(env, "TestCase::NativeAPI", "$LONG_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_float_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, float value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_float function, but you can specify the class name directry.
set_class_var_float
int32_t e; env->set_class_var_float_by_name(env, "TestCase::NativeAPI", "$FLOAT_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_double_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, double value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_double function, but you can specify the class name directry.
set_class_var_double
int32_t e; env->set_class_var_double_by_name(env, "TestCase::NativeAPI", "$DOUBLE_VALUE", 15, &e, __FILE__, __LINE__); if (e) { return e; }
void (*set_class_var_object_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, const char* signature, void* value, int32_t* exception_flag, const char* file, int32_t line);
This is same as set_class_var_object function, but you can specify the class name directry.
set_class_var_object
int32_t e; env->set_class_var_object_by_name(env, "TestCase::NativeAPI", "$MINIMAL_VALUE", "TestCase::Minimal", minimal, &e, __FILE__, __LINE__); if (e) { return e; }
int8_t (*get_class_var_byte_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_byte function, but you can specify the class name directry.
get_class_var_byte
int32_t e; int8_t value = env->get_class_var_byte_by_name(env, "TestCase::NativeAPI", "$BYTE_VALUE", &e, __FILE__, __LINE__); if (e) { return e; }
int16_t (*get_class_var_short_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_short function, but you can specify the class name directry.
get_class_var_short
int32_t e; int16_t value = env->get_class_var_short_by_name(env, "TestCase::NativeAPI", "$SHORT_VALUE", &e, __FILE__, __LINE__); if (e) { return e; }
int32_t (*get_class_var_int_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_int function, but you can specify the class name directry.
get_class_var_int
int64_t (*get_class_var_long_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_long function, but you can specify the class name directry.
get_class_var_long
int32_t e; int64_t value = env->get_class_var_long_by_name(env, "TestCase::NativeAPI", "$LONG_VALUE", &e, __FILE__, __LINE__); if (e) { return e; }
float (*get_class_var_float_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_float function, but you can specify the class name directry.
get_class_var_float
int32_t e; float value = env->get_class_var_float_by_name(env, "TestCase::NativeAPI", "$FLOAT_VALUE", &e, __FILE__, __LINE__); if (e) { return e; }
double (*get_class_var_double_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_double function, but you can specify the class name directry.
get_class_var_double
int32_t e; double value = env->get_class_var_double_by_name(env, "TestCase::NativeAPI", "$DOUBLE_VALUE", &e, __FILE__, __LINE__); if (e) { return e; }
void* (*get_class_var_object_by_name)(SPVM_ENV* env, const char* class_name, const char* class_var_name, const char* signature, int32_t* exception_flag, const char* file, int32_t line);
This is same as get_class_var_object function, but you can specify the class name directry.
get_class_var_object
int32_t e; void* value = env->get_class_var_object_by_name(env, "TestCase::NativeAPI", "$MINIMAL_VALUE", "TestCase::Minimal", &e, __FILE__, __LINE__); if (e) { return e; }
int32_t (*call_class_method_by_name)(SPVM_ENV* env, const char* class_name, const char* method_name, const char* signature, SPVM_VALUE* stack, const char* file, int32_t line);
This is same as call_spvm_method function, but you can specify the class name and sub name directry.
call_spvm_method
int32_t output; { stack[0].ival = 5; int32_t exception_flag = env->call_spvm_method_by_name(env, "TestCase::NativeAPI", "my_value", "int(int)", stack, __FILE__, __LINE__); if (exception_flag) { return exception_flag; } output = stack[0].ival; }
int32_t (*call_instance_method_by_name)(SPVM_ENV* env, void* object, const char* method_name, const char* signature, SPVM_VALUE* stack, const char* file, int32_t line);
const char* (*get_field_string_chars_by_name)(SPVM_ENV* env, void* object, const char* class_name, const char* field_name, int32_t* exception_flag, const char* file, int32_t line);
void* any_object_basic_type_id;
Basic type ID of any object type. This is used internally.
void* (*dump_raw)(SPVM_ENV* env, void* object);
Get the string which dump the object. The string is the same as the return value of dump operator.
dump
void* (*dump)(SPVM_ENV* env, void* object);
Do the same as dump_raw, and add the created string object to the mortal stack of the environment. Use this function in normal use instead of dump_raw.
dump_raw
Alias for "call_spvm_method"
int32_t (*get_instance_method_id_static)(SPVM_ENV* env, const char* class_name, const char* method_name, const char* signature);
Get a instance method ID by the class name, the method name, and the method signature. If the instance method does not exists, a negative value is returned.
int32_t method_id = env->get_instance_method_id_static(env, "Foo", "get", "int(long,string)");
Native APIs have indexes which correspond to the names. These indexes are permanently same for the binary compatibility. When a new Native API is added, it will be added to the end.
0 class_vars_heap 1 object_header_byte_size 2 object_weaken_backref_head_offset 3 object_ref_count_offset 4 object_basic_type_id_offset 5 object_type_dimension_offset 6 object_type_category_offset 7 object_flag_offset 8 object_length_offset 9 byte_object_basic_type_id 10 short_object_basic_type_id 11 int_object_basic_type_id 12 long_object_basic_type_id 13 float_object_basic_type_id 14 double_object_basic_type_id 15 compiler 16 exception_object 17 native_mortal_stack 18 native_mortal_stack_top 19 native_mortal_stack_capacity 20 get_basic_type_id 21 get_field_id 22 get_field_offset 23 get_class_var_id 24 get_class_method_id 25 get_instance_method_id 26 new_object_raw 27 new_object 28 new_byte_array_raw 29 new_byte_array 30 new_short_array_raw 31 new_short_array 32 new_int_array_raw 33 new_int_array 34 new_long_array_raw 35 new_long_array 36 new_float_array_raw 37 new_float_array 38 new_double_array_raw 39 new_double_array 40 new_object_array_raw 41 new_object_array 42 new_muldim_array_raw 43 new_muldim_array 44 new_mulnum_array_raw 45 new_mulnum_array 46 new_string_nolen_raw 47 new_string_nolen 48 new_string_raw 49 new_string 50 new_pointer_raw 51 new_pointer 52 concat_raw 53 concat 54 new_stack_trace_raw 55 new_stack_trace 56 length 57 get_elems_byte 58 get_elems_short 59 get_elems_int 60 get_elems_long 61 get_elems_float 62 get_elems_double 63 get_elem_object 64 set_elem_object 65 get_field_byte 66 get_field_short 67 get_field_int 68 get_field_long 69 get_field_float 70 get_field_double 71 get_field_object 72 set_field_byte 73 set_field_short 74 set_field_int 75 set_field_long 76 set_field_float 77 set_field_double 78 set_field_object 79 get_class_var_byte 80 get_class_var_short 81 get_class_var_int 82 get_class_var_long 83 get_class_var_float 84 get_class_var_double 85 get_class_var_object 86 set_class_var_byte 87 set_class_var_short 88 set_class_var_int 89 set_class_var_long 90 set_class_var_float 91 set_class_var_double 92 set_class_var_object 93 get_pointer 94 set_pointer 95 call_spvm_method 96 get_exception 97 set_exception 98 get_ref_count 99 inc_ref_count 100 dec_ref_count 101 enter_scope 102 push_mortal 103 leave_scope 104 remove_mortal 105 is_type 106 has_callback 107 get_object_basic_type_id 108 get_object_type_dimension 109 weaken 110 isweak 111 unweaken 112 alloc_memory_block_zero 113 free_memory_block 114 get_memory_blocks_count 115 get_type_name_raw 116 get_type_name 117 new_env 118 free_env 119 memory_blocks_count 120 get_chars 121 die 122 new_object_by_name 123 new_pointer_by_name 124 set_field_byte_by_name 125 set_field_short_by_name 126 set_field_int_by_name 127 set_field_long_by_name 128 set_field_float_by_name 129 set_field_double_by_name 130 set_field_object_by_name 131 get_field_byte_by_name 132 get_field_short_by_name 133 get_field_int_by_name 134 get_field_long_by_name 135 get_field_float_by_name 136 get_field_double_by_name 137 get_field_object_by_name 138 set_class_var_byte_by_name 139 set_class_var_short_by_name 140 set_class_var_int_by_name 141 set_class_var_long_by_name 142 set_class_var_float_by_name 143 set_class_var_double_by_name 144 set_class_var_object_by_name 145 get_class_var_byte_by_name 146 get_class_var_short_by_name 147 get_class_var_int_by_name 148 get_class_var_long_by_name 149 get_class_var_float_by_name 150 get_class_var_double_by_name 151 get_class_var_object_by_name 152 call_spvm_method_by_name 153 call_callback_method_by_name 154 get_field_string_chars_by_name 155 any_object_basic_type_id 156 dump_raw 157 dump 158 call_class_method 159 call_instance_method 160 get_instance_method_id_static
Examples using SPVM Native APIs
To install SPVM, copy and paste the appropriate command in to your terminal.
cpanm
cpanm SPVM
CPAN shell
perl -MCPAN -e shell install SPVM
For more information on module installation, please visit the detailed CPAN module installation guide.