PythonExtra/py/binary.c

#include <stdint.h>
#include <stdlib.h>
#include <assert.h>

#include "misc.h"
#include "mpconfig.h"
#include "qstr.h"
#include "obj.h"
#include "binary.h"

// Helpers to work with binary-encoded data

int mp_binary_get_size(char struct_type, char val_type, uint *palign) {
    int size = 0;
    int align = 1;
    switch (struct_type) {
        case '<': case '>':
            switch (val_type) {
                case 'b': case 'B':
                    size = 1; break;
                case 'h': case 'H':
                    size = 2; break;
                case 'i': case 'I':
                    size = 4; break;
                case 'l': case 'L':
                    size = 4; break;
                case 'q': case 'Q':
                    size = 8; break;
            }
            break;
        case '@': {
            // TODO:
            // The simplest heuristic for alignment is to align by value
            // size, but that doesn't work for "bigger than int" types,
            // for example, long long may very well have long alignment
            // So, we introduce separate alignment handling, but having
            // formal support for that is different from actually supporting
            // particular (or any) ABI.
            switch (val_type) {
                case BYTEARRAY_TYPECODE:
                case 'b': case 'B':
                    align = size = 1; break;
                case 'h': case 'H':
                    align = size = sizeof(short); break;
                case 'i': case 'I':
                    align = size = sizeof(int); break;
                case 'l': case 'L':
                    align = size = sizeof(long); break;
                case 'q': case 'Q':
                    // TODO: This is for x86
                    align = sizeof(int); size = sizeof(long long); break;
            }
        }
    }
    if (palign != NULL) {
        *palign = align;
    }
    return size;
}

mp_obj_t mp_binary_get_val_array(char typecode, void *p, int index) {
    machine_int_t val = 0;
    switch (typecode) {
        case 'b':
            val = ((int8_t*)p)[index];
            break;
        case BYTEARRAY_TYPECODE:
        case 'B':
            val = ((uint8_t*)p)[index];
            break;
        case 'h':
            val = ((int16_t*)p)[index];
            break;
        case 'H':
            val = ((uint16_t*)p)[index];
            break;
        case 'i':
        case 'l':
            return mp_obj_new_int(((int32_t*)p)[index]);
        case 'I':
        case 'L':
            return mp_obj_new_int_from_uint(((uint32_t*)p)[index]);
#if MICROPY_LONGINT_IMPL != MICROPY_LONGINT_IMPL_NONE
        case 'q':
        case 'Q':
            // TODO: Explode API more to cover signedness
            return mp_obj_new_int_from_ll(((long long*)p)[index]);
#endif
#if MICROPY_ENABLE_FLOAT
        case 'f':
            return mp_obj_new_float(((float*)p)[index]);
        case 'd':
            return mp_obj_new_float(((double*)p)[index]);
#endif
    }
    return MP_OBJ_NEW_SMALL_INT(val);
}

#define is_signed(typecode) (typecode > 'Z')
mp_obj_t mp_binary_get_val(char struct_type, char val_type, byte **ptr) {
    byte *p = *ptr;
    uint align;

    int size = mp_binary_get_size(struct_type, val_type, &align);
    if (struct_type == '@') {
        // Make pointer aligned
        p = (byte*)(((machine_uint_t)p + align - 1) & ~(align - 1));
        #if MP_ENDIANNESS_LITTLE
        struct_type = '<';
        #else
        struct_type = '>';
        #endif
    }

    int delta;
    if (struct_type == '<') {
        delta = -1;
        p += size - 1;
    } else {
        delta = 1;
    }

    machine_int_t val = 0;
    if (is_signed(val_type) && *p & 0x80) {
        val = -1;
    }
    for (uint i = 0; i < size; i++) {
        val <<= 8;
        val |= *p;
        p += delta;
    }

    *ptr += size;
    if (is_signed(val_type)) {
        return mp_obj_new_int(val);
    } else {
        return mp_obj_new_int_from_uint(val);
    }
}

void mp_binary_set_val_array(char typecode, void *p, int index, mp_obj_t val_in) {
    switch (typecode) {
#if MICROPY_ENABLE_FLOAT
        case 'f':
            ((float*)p)[index] = mp_obj_float_get(val_in);
            break;
        case 'd':
            ((double*)p)[index] = mp_obj_float_get(val_in);
            break;
#endif
        default:
            mp_binary_set_val_array_from_int(typecode, p, index, mp_obj_get_int(val_in));
    }
}

void mp_binary_set_val_array_from_int(char typecode, void *p, int index, machine_int_t val) {
    switch (typecode) {
        case 'b':
            ((int8_t*)p)[index] = val;
            break;
        case BYTEARRAY_TYPECODE:
        case 'B':
            val = ((uint8_t*)p)[index] = val;
            break;
        case 'h':
            val = ((int16_t*)p)[index] = val;
            break;
        case 'H':
            val = ((uint16_t*)p)[index] = val;
            break;
        case 'i':
        case 'l':
            ((int32_t*)p)[index] = val;
            break;
        case 'I':
        case 'L':
            ((uint32_t*)p)[index] = val;
            break;
#if MICROPY_LONGINT_IMPL != MICROPY_LONGINT_IMPL_NONE
        case 'q':
        case 'Q':
            assert(0);
            ((long long*)p)[index] = val;
            break;
#endif
#if MICROPY_ENABLE_FLOAT
        case 'f':
            ((float*)p)[index] = val;
            break;
        case 'd':
            ((double*)p)[index] = val;
            break;
#endif
    }
}
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`#include <stdint.h>`
modstruct: Fix .calcsize() to account for struct type/alignment. 2014-04-19 00:25:49 +02:00			`#include <stdlib.h>`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`#include <assert.h>`

			`#include "misc.h"`
			`#include "mpconfig.h"`
			`#include "qstr.h"`
			`#include "obj.h"`
			`#include "binary.h"`

			`// Helpers to work with binary-encoded data`

modstruct: Fix .calcsize() to account for struct type/alignment. 2014-04-19 00:25:49 +02:00			`int mp_binary_get_size(char struct_type, char val_type, uint *palign) {`
			`int size = 0;`
			`int align = 1;`
			`switch (struct_type) {`
			`case '<': case '>':`
			`switch (val_type) {`
			`case 'b': case 'B':`
			`size = 1; break;`
			`case 'h': case 'H':`
			`size = 2; break;`
			`case 'i': case 'I':`
			`size = 4; break;`
			`case 'l': case 'L':`
			`size = 4; break;`
			`case 'q': case 'Q':`
			`size = 8; break;`
			`}`
			`break;`
			`case '@': {`
			`// TODO:`
			`// The simplest heuristic for alignment is to align by value`
			`// size, but that doesn't work for "bigger than int" types,`
			`// for example, long long may very well have long alignment`
			`// So, we introduce separate alignment handling, but having`
			`// formal support for that is different from actually supporting`
			`// particular (or any) ABI.`
			`switch (val_type) {`
			`case BYTEARRAY_TYPECODE:`
			`case 'b': case 'B':`
			`align = size = 1; break;`
			`case 'h': case 'H':`
			`align = size = sizeof(short); break;`
			`case 'i': case 'I':`
			`align = size = sizeof(int); break;`
			`case 'l': case 'L':`
			`align = size = sizeof(long); break;`
			`case 'q': case 'Q':`
			`// TODO: This is for x86`
			`align = sizeof(int); size = sizeof(long long); break;`
			`}`
			`}`
objarray: Refactor to use array accessors from binary.c . 2014-02-14 19:21:50 +01:00			`}`
modstruct: Fix .calcsize() to account for struct type/alignment. 2014-04-19 00:25:49 +02:00			`if (palign != NULL) {`
			`*palign = align;`
			`}`
			`return size;`
objarray: Refactor to use array accessors from binary.c . 2014-02-14 19:21:50 +01:00			`}`

binary: Rename array accessors for clarity. 2014-04-11 02:46:09 +02:00			`mp_obj_t mp_binary_get_val_array(char typecode, void *p, int index) {`
mp_binary_get_val(): Fix value type. 2014-02-14 23:28:41 +01:00			`machine_int_t val = 0;`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`switch (typecode) {`
			`case 'b':`
			`val = ((int8_t*)p)[index];`
			`break;`
			`case BYTEARRAY_TYPECODE:`
			`case 'B':`
			`val = ((uint8_t*)p)[index];`
			`break;`
			`case 'h':`
			`val = ((int16_t*)p)[index];`
			`break;`
			`case 'H':`
			`val = ((uint16_t*)p)[index];`
			`break;`
			`case 'i':`
			`case 'l':`
			`return mp_obj_new_int(((int32_t*)p)[index]);`
			`case 'I':`
			`case 'L':`
			`return mp_obj_new_int_from_uint(((uint32_t*)p)[index]);`
py: Revent some long int configuration. 2014-02-16 00:02:00 +01:00			`#if MICROPY_LONGINT_IMPL != MICROPY_LONGINT_IMPL_NONE`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`case 'q':`
			`case 'Q':`
			`// TODO: Explode API more to cover signedness`
			`return mp_obj_new_int_from_ll(((long long*)p)[index]);`
			`#endif`
			`#if MICROPY_ENABLE_FLOAT`
			`case 'f':`
			`return mp_obj_new_float(((float*)p)[index]);`
			`case 'd':`
			`return mp_obj_new_float(((double*)p)[index]);`
			`#endif`
			`}`
			`return MP_OBJ_NEW_SMALL_INT(val);`
			`}`

modstruct: Refactor to support both LE and BE packed structs. 2014-04-10 21:19:32 +02:00			`#define is_signed(typecode) (typecode > 'Z')`
modstruct: Basic implementation of native struct alignment and types. 2014-04-11 02:47:21 +02:00			`mp_obj_t mp_binary_get_val(char struct_type, char val_type, byte **ptr) {`
py: Start implementing "struct" module. Only calcsize() and unpack() functions provided so far, for little-endian byte order. Format strings don't support repition spec (like "2b3i"). Unfortunately, dealing with all the various binary type sizes and alignments will lead to quite a bloated "binary" helper functions - if optimizing for speed. Need to think if using dynamic parametrized algos makes more sense. 2014-04-10 02:45:38 +02:00			`byte p = ptr;`
modstruct: Fix .calcsize() to account for struct type/alignment. 2014-04-19 00:25:49 +02:00			`uint align;`

			`int size = mp_binary_get_size(struct_type, val_type, &align);`
			`if (struct_type == '@') {`
			`// Make pointer aligned`
			`p = (byte*)(((machine_uint_t)p + align - 1) & ~(align - 1));`
			`#if MP_ENDIANNESS_LITTLE`
			`struct_type = '<';`
			`#else`
			`struct_type = '>';`
			`#endif`
py: Start implementing "struct" module. Only calcsize() and unpack() functions provided so far, for little-endian byte order. Format strings don't support repition spec (like "2b3i"). Unfortunately, dealing with all the various binary type sizes and alignments will lead to quite a bloated "binary" helper functions - if optimizing for speed. Need to think if using dynamic parametrized algos makes more sense. 2014-04-10 02:45:38 +02:00			`}`
modstruct: Refactor to support both LE and BE packed structs. 2014-04-10 21:19:32 +02:00
			`int delta;`
modstruct: Basic implementation of native struct alignment and types. 2014-04-11 02:47:21 +02:00			`if (struct_type == '<') {`
modstruct: Refactor to support both LE and BE packed structs. 2014-04-10 21:19:32 +02:00			`delta = -1;`
			`p += size - 1;`
			`} else {`
			`delta = 1;`
			`}`

			`machine_int_t val = 0;`
modstruct: Basic implementation of native struct alignment and types. 2014-04-11 02:47:21 +02:00			`if (is_signed(val_type) && *p & 0x80) {`
modstruct: Refactor to support both LE and BE packed structs. 2014-04-10 21:19:32 +02:00			`val = -1;`
			`}`
			`for (uint i = 0; i < size; i++) {`
			`val <<= 8;`
			`val \|= *p;`
			`p += delta;`
			`}`

modstruct: Basic implementation of native struct alignment and types. 2014-04-11 02:47:21 +02:00			`*ptr += size;`
			`if (is_signed(val_type)) {`
modstruct: Refactor to support both LE and BE packed structs. 2014-04-10 21:19:32 +02:00			`return mp_obj_new_int(val);`
			`} else {`
			`return mp_obj_new_int_from_uint(val);`
			`}`
py: Start implementing "struct" module. Only calcsize() and unpack() functions provided so far, for little-endian byte order. Format strings don't support repition spec (like "2b3i"). Unfortunately, dealing with all the various binary type sizes and alignments will lead to quite a bloated "binary" helper functions - if optimizing for speed. Need to think if using dynamic parametrized algos makes more sense. 2014-04-10 02:45:38 +02:00			`}`

binary: Rename array accessors for clarity. 2014-04-11 02:46:09 +02:00			`void mp_binary_set_val_array(char typecode, void *p, int index, mp_obj_t val_in) {`
py: Add mp_binary_set_val_array_from_int, to store an int directly. 2014-04-19 00:28:12 +02:00			`switch (typecode) {`
			`#if MICROPY_ENABLE_FLOAT`
			`case 'f':`
			`((float*)p)[index] = mp_obj_float_get(val_in);`
			`break;`
			`case 'd':`
			`((double*)p)[index] = mp_obj_float_get(val_in);`
			`break;`
			`#endif`
			`default:`
			`mp_binary_set_val_array_from_int(typecode, p, index, mp_obj_get_int(val_in));`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`}`
py: Add mp_binary_set_val_array_from_int, to store an int directly. 2014-04-19 00:28:12 +02:00			`}`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00
py: Add mp_binary_set_val_array_from_int, to store an int directly. 2014-04-19 00:28:12 +02:00			`void mp_binary_set_val_array_from_int(char typecode, void *p, int index, machine_int_t val) {`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`switch (typecode) {`
			`case 'b':`
			`((int8_t*)p)[index] = val;`
			`break;`
			`case BYTEARRAY_TYPECODE:`
			`case 'B':`
			`val = ((uint8_t*)p)[index] = val;`
			`break;`
			`case 'h':`
			`val = ((int16_t*)p)[index] = val;`
			`break;`
			`case 'H':`
			`val = ((uint16_t*)p)[index] = val;`
			`break;`
			`case 'i':`
			`case 'l':`
			`((int32_t*)p)[index] = val;`
			`break;`
			`case 'I':`
			`case 'L':`
			`((uint32_t*)p)[index] = val;`
			`break;`
			`#if MICROPY_LONGINT_IMPL != MICROPY_LONGINT_IMPL_NONE`
			`case 'q':`
			`case 'Q':`
			`assert(0);`
			`((long long*)p)[index] = val;`
			`break;`
			`#endif`
			`#if MICROPY_ENABLE_FLOAT`
			`case 'f':`
py: Add mp_binary_set_val_array_from_int, to store an int directly. 2014-04-19 00:28:12 +02:00			`((float*)p)[index] = val;`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`break;`
			`case 'd':`
py: Add mp_binary_set_val_array_from_int, to store an int directly. 2014-04-19 00:28:12 +02:00			`((double*)p)[index] = val;`
ffi: Implement ffivar.get()/set() methods. Done by introducing another factored out helper API in binary.c. This API can be reused also by array and struct modules. 2014-02-14 16:16:35 +01:00			`break;`
			`#endif`
			`}`
			`}`