Summary: How does the compiler statically determine the size of a C++ class during compilation?
Details:
I'm trying to understand what the rules are for determining how much memory a class will use, and also how the memory will be aligned.
For example the following code declares 4 classes. The first 2 are each 16 bytes. But the 3 is 48 bytes, even though it contains the same data members as the first 2. While the fourth class has the same data members as the third, just in a different order, but it is 32 bytes.
#include <xmmintrin.h>
#include <stdio.h>
class TestClass1 {
__m128i vect;
};
class TestClass2 {
char buf[8];
char buf2[8];
};
class TestClass3 {
char buf[8];
__m128i vect;
char buf2[8];
};
class TestClass4 {
char buf[8];
char buf2[8];
__m128i vect;
};
TestClass1 *ptr1;
TestClass2 *ptr2;
TestClass3 *ptr3;
TestClass4 *ptr4;
int main() {
ptr1 = new TestClass1();
ptr2 = new TestClass2();
ptr3 = new TestClass3();
ptr4 = new TestClass4();
printf("sizeof TestClass1 is: %lu\t TestClass2 is: %lu\t TestClass3 is: %lu\t TestClass4 is: %lu\n", sizeof(*ptr1), sizeof(*ptr2), sizeof(*ptr3), sizeof(*ptr4));
return 0;
}
I know that the answer has something to do with alignment of the data members of the class. But I am trying to understand exactly what these rules are and how they get applied during the compilation steps because I have a class that has a __m128i data member, but the data member is not 16-byte aligned and this results in a segfault when the compiler generates code using movaps to access the data.
For POD (plain old data), the rules are typically:
Each member in the structure has some size s and some alignment requirement a.
The compiler starts with a size S set to zero and an alignment requirement A set to one (byte).
The compiler processes each member in the structure in order:
Consider the member’s alignment requirement a. If S is not currently a multiple of a, then add just enough bytes to S so that it is a multiple of a. This determines where the member will go; it will go at offset S from the beginning of the structure (for the current value of S).
Set A to the least common multiple1 of A and a.
Add s to S, to set aside space for the member.
When the above process is done for each member, consider the structure’s alignment requirement A. If S is not currently a multiple of A, then add just enough to S so that it is a multiple of A.
The size of the structure is the value of S when the above is done.
Additionally:
If any member is an array, its size is the number of elements multiplied by the size of each element, and its alignment requirement is the alignment requirement of an element.
If any member is a structure, its size and alignment requirement are calculated as above.
If any member is a union, its size is the size of its largest member plus just enough to make it a multiple of the least common multiple1 of the alignments of all the members.
Consider your TestClass3:
S starts at 0 and A starts at 1.
char buf[8] requires 8 bytes and alignment 1, so S is increased by 8 to 8, and A remains 1.
__m128i vect requires 16 bytes and alignment 16. First, S must be increased to 16 to give the correct alignment. Then A must be increased to 16. Then S must be increased by 16 to make space for vect, so S is now 32.
char buf2[8] requires 8 bytes and alignment 1, so S is increased by 8 to 24, and A remains 16.
At the end, S is 24, which is not a multiple of A (16), so S must be increased by 8 to 32.
So the size of TestClass3 is 32 bytes.
For elementary types (int, double, et cetera), the alignment requirements are implementation-defined and are usually largely determined by the hardware. On many processors, it is faster to load and store data when it has a certain alignment (usually when its address in memory is a multiple of its size). Beyond this, the rules above follow largely from logic; they put each member where it must be to satisfy alignment requirements without using more space than necessary.
Footnote
1 I have worded this for a general case as using the least common multiple of alignment requirements. However, since alignment requirements are always powers of two, the least common multiple of any set of alignment requirements is the largest of them.
It is entirely up to the compiler how the size of a class is determined. A compiler will usually compile to match a certain application binary interface, which is platform dependent.
The behaviour you've observed, however, is pretty typical. The compiler is trying to align the members so that they each begin at a multiple of their size. In the case of TestClass3, the one of the members is of type __m128i and sizeof(__m128i) == 16. So it will try to align that member to begin at a byte that is a multiple of 16. The first member is of type char[8] so takes up 8 bytes. If the compiler were to place the _m128i object directly after this first member, it would start at position 8, which is not a multiple of 16:
0 8 16 24 32 48
┌───────────────┬───────────────────────────────┬───────────────┬┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄
│ char[8] │ __m128i │ char[8] │
└───────────────┴───────────────────────────────┴───────────────┴┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄
So instead it prefers to do this:
0 8 16 24 32 48
┌───────────────┬┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┬───────────────────────────────┬───────────────┐┄┄┄
│ char[8] │ │ __m128i │ char[8] │
└───────────────┴┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┴───────────────────────────────┴───────────────┘┄┄┄
This gives it a size of 48 bytes.
When you reorder the members to get TestClass4 the layout becomes:
0 8 16 24 32 48
┌───────────────┬───────────────┬───────────────────────────────┬┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄
│ char[8] │ char[8] │ __m128i │
└───────────────┴───────────────┴───────────────────────────────┴┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄┄
Now everything is correctly aligned - the arrays are at offsets that are multiple of 1 (the size of their elements) and the __m128i object is at an offset that is a multiple of 16 - and the total size is 32 bytes.
The reason the compiler doesn't just do this rearrangement itself is because the standard specifies that later members of a class should have higher addresses:
Nonstatic data members of a (non-union) class with the same access control (Clause 11) are allocated so that later members have higher addresses within a class object.
The rules are set in stone by the Application Binary Interface specification in use, which ensures compatibility between different systems for programs sharing this interface.
For GCC, this is the Itanium ABI.
(Unfortunately it is no longer publicly available, though I did find a mirror.)
if you want to ensure the allignment you should use the "pragma pack(1)" in your h file
look at this post:
http://tedlogan.com/techblog2.html
Why does the sizeof operator return a size larger for a structure than the total sizes of the structure's members?
This is because of padding added to satisfy alignment constraints. Data structure alignment impacts both performance and correctness of programs:
Mis-aligned access might be a hard error (often SIGBUS).
Mis-aligned access might be a soft error.
Either corrected in hardware, for a modest performance-degradation.
Or corrected by emulation in software, for a severe performance-degradation.
In addition, atomicity and other concurrency-guarantees might be broken, leading to subtle errors.
Here's an example using typical settings for an x86 processor (all used 32 and 64 bit modes):
struct X
{
short s; /* 2 bytes */
/* 2 padding bytes */
int i; /* 4 bytes */
char c; /* 1 byte */
/* 3 padding bytes */
};
struct Y
{
int i; /* 4 bytes */
char c; /* 1 byte */
/* 1 padding byte */
short s; /* 2 bytes */
};
struct Z
{
int i; /* 4 bytes */
short s; /* 2 bytes */
char c; /* 1 byte */
/* 1 padding byte */
};
const int sizeX = sizeof(struct X); /* = 12 */
const int sizeY = sizeof(struct Y); /* = 8 */
const int sizeZ = sizeof(struct Z); /* = 8 */
One can minimize the size of structures by sorting members by alignment (sorting by size suffices for that in basic types) (like structure Z in the example above).
IMPORTANT NOTE: Both the C and C++ standards state that structure alignment is implementation-defined. Therefore each compiler may choose to align data differently, resulting in different and incompatible data layouts. For this reason, when dealing with libraries that will be used by different compilers, it is important to understand how the compilers align data. Some compilers have command-line settings and/or special #pragma statements to change the structure alignment settings.
Packing and byte alignment, as described in the C FAQ here:
It's for alignment. Many processors can't access 2- and 4-byte
quantities (e.g. ints and long ints) if they're crammed in
every-which-way.
Suppose you have this structure:
struct {
char a[3];
short int b;
long int c;
char d[3];
};
Now, you might think that it ought to be possible to pack this
structure into memory like this:
+-------+-------+-------+-------+
| a | b |
+-------+-------+-------+-------+
| b | c |
+-------+-------+-------+-------+
| c | d |
+-------+-------+-------+-------+
But it's much, much easier on the processor if the compiler arranges
it like this:
+-------+-------+-------+
| a |
+-------+-------+-------+
| b |
+-------+-------+-------+-------+
| c |
+-------+-------+-------+-------+
| d |
+-------+-------+-------+
In the packed version, notice how it's at least a little bit hard for
you and me to see how the b and c fields wrap around? In a nutshell,
it's hard for the processor, too. Therefore, most compilers will pad
the structure (as if with extra, invisible fields) like this:
+-------+-------+-------+-------+
| a | pad1 |
+-------+-------+-------+-------+
| b | pad2 |
+-------+-------+-------+-------+
| c |
+-------+-------+-------+-------+
| d | pad3 |
+-------+-------+-------+-------+
If you want the structure to have a certain size with GCC for example use __attribute__((packed)).
On Windows you can set the alignment to one byte when using the cl.exe compier with the /Zp option.
Usually it is easier for the CPU to access data that is a multiple of 4 (or 8), depending platform and also on the compiler.
So it is a matter of alignment basically.
You need to have good reasons to change it.
This can be due to byte alignment and padding so that the structure comes out to an even number of bytes (or words) on your platform. For example in C on Linux, the following 3 structures:
#include "stdio.h"
struct oneInt {
int x;
};
struct twoInts {
int x;
int y;
};
struct someBits {
int x:2;
int y:6;
};
int main (int argc, char** argv) {
printf("oneInt=%zu\n",sizeof(struct oneInt));
printf("twoInts=%zu\n",sizeof(struct twoInts));
printf("someBits=%zu\n",sizeof(struct someBits));
return 0;
}
Have members who's sizes (in bytes) are 4 bytes (32 bits), 8 bytes (2x 32 bits) and 1 byte (2+6 bits) respectively. The above program (on Linux using gcc) prints the sizes as 4, 8, and 4 - where the last structure is padded so that it is a single word (4 x 8 bit bytes on my 32bit platform).
oneInt=4
twoInts=8
someBits=4
See also:
for Microsoft Visual C:
http://msdn.microsoft.com/en-us/library/2e70t5y1%28v=vs.80%29.aspx
and GCC claim compatibility with Microsoft's compiler.:
https://gcc.gnu.org/onlinedocs/gcc-4.6.4/gcc/Structure_002dPacking-Pragmas.html
In addition to the previous answers, please note that regardless the packaging, there is no members-order-guarantee in C++. Compilers may (and certainly do) add virtual table pointer and base structures' members to the structure. Even the existence of virtual table is not ensured by the standard (virtual mechanism implementation is not specified) and therefore one can conclude that such guarantee is just impossible.
I'm quite sure member-order is guaranteed in C, but I wouldn't count on it, when writing a cross-platform or cross-compiler program.
The size of a structure is greater than the sum of its parts because of what is called packing. A particular processor has a preferred data size that it works with. Most modern processors' preferred size if 32-bits (4 bytes). Accessing the memory when data is on this kind of boundary is more efficient than things that straddle that size boundary.
For example. Consider the simple structure:
struct myStruct
{
int a;
char b;
int c;
} data;
If the machine is a 32-bit machine and data is aligned on a 32-bit boundary, we see an immediate problem (assuming no structure alignment). In this example, let us assume that the structure data starts at address 1024 (0x400 - note that the lowest 2 bits are zero, so the data is aligned to a 32-bit boundary). The access to data.a will work fine because it starts on a boundary - 0x400. The access to data.b will also work fine, because it is at address 0x404 - another 32-bit boundary. But an unaligned structure would put data.c at address 0x405. The 4 bytes of data.c are at 0x405, 0x406, 0x407, 0x408. On a 32-bit machine, the system would read data.c during one memory cycle, but would only get 3 of the 4 bytes (the 4th byte is on the next boundary). So, the system would have to do a second memory access to get the 4th byte,
Now, if instead of putting data.c at address 0x405, the compiler padded the structure by 3 bytes and put data.c at address 0x408, then the system would only need 1 cycle to read the data, cutting access time to that data element by 50%. Padding swaps memory efficiency for processing efficiency. Given that computers can have huge amounts of memory (many gigabytes), the compilers feel that the swap (speed over size) is a reasonable one.
Unfortunately, this problem becomes a killer when you attempt to send structures over a network or even write the binary data to a binary file. The padding inserted between elements of a structure or class can disrupt the data sent to the file or network. In order to write portable code (one that will go to several different compilers), you will probably have to access each element of the structure separately to ensure the proper "packing".
On the other hand, different compilers have different abilities to manage data structure packing. For example, in Visual C/C++ the compiler supports the #pragma pack command. This will allow you to adjust data packing and alignment.
For example:
#pragma pack 1
struct MyStruct
{
int a;
char b;
int c;
short d;
} myData;
I = sizeof(myData);
I should now have the length of 11. Without the pragma, I could be anything from 11 to 14 (and for some systems, as much as 32), depending on the default packing of the compiler.
C99 N1256 standard draft
http://www.open-std.org/JTC1/SC22/WG14/www/docs/n1256.pdf
6.5.3.4 The sizeof operator:
3 When applied to an operand that has structure or union type,
the result is the total number of bytes in such an object,
including internal and trailing padding.
6.7.2.1 Structure and union specifiers:
13 ... There may be unnamed
padding within a structure object, but not at its beginning.
and:
15 There may be unnamed padding at the end of a structure or union.
The new C99 flexible array member feature (struct S {int is[];};) may also affect padding:
16 As a special case, the last element of a structure with more than one named member may
have an incomplete array type; this is called a flexible array member. In most situations,
the flexible array member is ignored. In particular, the size of the structure is as if the
flexible array member were omitted except that it may have more trailing padding than
the omission would imply.
Annex J Portability Issues reiterates:
The following are unspecified: ...
The value of padding bytes when storing values in structures or unions (6.2.6.1)
C++11 N3337 standard draft
http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2012/n3337.pdf
5.3.3 Sizeof:
2 When applied
to a class, the result is the number of bytes in an object of that class including any padding required for
placing objects of that type in an array.
9.2 Class members:
A pointer to a standard-layout struct object, suitably converted using a reinterpret_cast, points to its
initial member (or if that member is a bit-field, then to the unit in which it resides) and vice versa. [ Note:
There might therefore be unnamed padding within a standard-layout struct object, but not at its beginning,
as necessary to achieve appropriate alignment. — end note ]
I only know enough C++ to understand the note :-)
It can do so if you have implicitly or explicitly set the alignment of the struct. A struct that is aligned 4 will always be a multiple of 4 bytes even if the size of its members would be something that's not a multiple of 4 bytes.
Also a library may be compiled under x86 with 32-bit ints and you may be comparing its components on a 64-bit process would would give you a different result if you were doing this by hand.
C language leaves compiler some freedom about the location of the structural elements in the memory:
memory holes may appear between any two components, and after the last component. It was due to the fact that certain types of objects on the target computer may be limited by the boundaries of addressing
"memory holes" size included in the result of sizeof operator. The sizeof only doesn't include size of the flexible array, which is available in C/C++
Some implementations of the language allow you to control the memory layout of structures through the pragma and compiler options
The C language provides some assurance to the programmer of the elements layout in the structure:
compilers required to assign a sequence of components increasing memory addresses
Address of the first component coincides with the start address of the structure
unnamed bit fields may be included in the structure to the required address alignments of adjacent elements
Problems related to the elements alignment:
Different computers line the edges of objects in different ways
Different restrictions on the width of the bit field
Computers differ on how to store the bytes in a word (Intel 80x86 and Motorola 68000)
How alignment works:
The volume occupied by the structure is calculated as the size of the aligned single element of an array of such structures. The structure should
end so that the first element of the next following structure does not the violate requirements of alignment
p.s More detailed info are available here: "Samuel P.Harbison, Guy L.Steele C A Reference, (5.6.2 - 5.6.7)"
The idea is that for speed and cache considerations, operands should be read from addresses aligned to their natural size. To make this happen, the compiler pads structure members so the following member or following struct will be aligned.
struct pixel {
unsigned char red; // 0
unsigned char green; // 1
unsigned int alpha; // 4 (gotta skip to an aligned offset)
unsigned char blue; // 8 (then skip 9 10 11)
};
// next offset: 12
The x86 architecture has always been able to fetch misaligned addresses. However, it's slower and when the misalignment overlaps two different cache lines, then it evicts two cache lines when an aligned access would only evict one.
Some architectures actually have to trap on misaligned reads and writes, and early versions of the ARM architecture (the one that evolved into all of today's mobile CPUs) ... well, they actually just returned bad data on for those. (They ignored the low-order bits.)
Finally, note that cache lines can be arbitrarily large, and the compiler doesn't attempt to guess at those or make a space-vs-speed tradeoff. Instead, the alignment decisions are part of the ABI and represent the minimum alignment that will eventually evenly fill up a cache line.
TL;DR: alignment is important.
In addition to the other answers, a struct can (but usually doesn't) have virtual functions, in which case the size of the struct will also include the space for the vtbl.
Among the other well-explained answers about memory alignment and structure padding/packing, there is something which I have discovered in the question itself by reading it carefully.
"Why isn't sizeof for a struct equal to the sum of sizeof of each member?"
"Why does the sizeof operator return a size larger for a structure than the total sizes of the structure's members"?
Both questions suggest something what is plain wrong. At least in a generic, non-example focused view, which is the case here.
The result of the sizeof operand applied to a structure object can be equal to the sum of sizeof applied to each member separately. It doesn't have to be larger/different.
If there is no reason for padding, no memory will be padded.
One most implementations, if the structure contains only members of the same type:
struct foo {
int a;
int b;
int c;
} bar;
Assuming sizeof(int) == 4, the size of the structure bar will be equal to the sum of the sizes of all members together, sizeof(bar) == 12. No padding done here.
Same goes for example here:
struct foo {
short int a;
short int b;
int c;
} bar;
Assuming sizeof(short int) == 2 and sizeof(int) == 4. The sum of allocated bytes for a and b is equal to the allocated bytes for c, the largest member and with that everything is perfectly aligned. Thus, sizeof(bar) == 8.
This is also object of the second most popular question regarding structure padding, here:
Memory alignment in C-structs
given a lot information(explanation) above.
And, I just would like to share some method in order to solve this issue.
You can avoid it by adding pragma pack
#pragma pack(push, 1)
// your structure
#pragma pack(pop)
Someone explain me how does the order of the member declaration inside a class determines the size of that class.
For Example :
class temp
{
public:
int i;
short s;
char c;
};
The size of above class is 8 bytes.
But when the order of the member declaration is changed as below
class temp
{
public:
char c;
int i;
short s;
};
then the size of class is 12 bytes.
How?
The reason behind above behavior is data structure alignment and padding. Basically if you are creating a 4 byte variable e.g. int, it will be aligned to a four byte boundary i.e. it will start from an address in memory, which is multiple of 4. Same applies to other data types. 2 byte short should start from even memory address and so on.
Hence if you have a 1 byte character declared before the int (assume 4 byte here), there will be 3 free bytes left in between. The common term used for them is 'padded'.
Data structure alignment
Another good pictorial explanation
Reason for alignment
Padding allows faster memory access i.e. for cpu, accessing memory areas that are aligned is faster e.g. reading a 4 byte aligned integer might take a single read call where as if an integer is located at a non aligned address range (say address 0x0002 - 0x0006), then it would take two memory reads to get this integer.
One way to force compiler to avoid alignment is (specific to gcc/g++) to use keyword 'packed' with the structure attribute. packed keyword Also the link specifies how to enforce alignment by a specific boundary of your choice (2, 4, 8 etc.) using the aligned keyword.
Best practice
It is always a good idea to structure your class/struct in a way that variables are already aligned with minimum padding. This reduces the size of the class overall plus it reduces the amount of work done by the compiler i.e. no rearrangement of structure. Also one should always access member variables by their names in the code, rather than trying to read a specific byte from structure assuming a value would be located at that byte.
Another useful SO question on performance advantage of alignment
For the sake of completion, following would still have a size of 8 bytes in your scenario (32 bit machine), but it won't get any better since full 8 bytes are now occupied, and there is no padding.
class temp
{
public:
int i;
short s;
char c;
char c2;
};
class temp
{
public:
int i; //size 4 alignment 4
short s; //size 2 alignment 2
char c; //size 1 alignment 1
}; //Size 8 alignment max(4,2,1)=4
temp[i[0-4];s[4-2];c[6-7]]] -> 8
Padding in (7-8)
class temp
{
public:
char c; //size 1 alignment 1
int i; //size 4 alignment 4
short s; //size 2 alignment 2
};//Size 12 alignment max(4,2,1)=4
temp[c[0-1];i[4-8];s[8-10]]] -> 12
Padding in (1-4) and (10-12)
Someone explain me how does the order of the member declaration inside a class determines the size of that class.
For Example :
class temp
{
public:
int i;
short s;
char c;
};
The size of above class is 8 bytes.
But when the order of the member declaration is changed as below
class temp
{
public:
char c;
int i;
short s;
};
then the size of class is 12 bytes.
How?
The reason behind above behavior is data structure alignment and padding. Basically if you are creating a 4 byte variable e.g. int, it will be aligned to a four byte boundary i.e. it will start from an address in memory, which is multiple of 4. Same applies to other data types. 2 byte short should start from even memory address and so on.
Hence if you have a 1 byte character declared before the int (assume 4 byte here), there will be 3 free bytes left in between. The common term used for them is 'padded'.
Data structure alignment
Another good pictorial explanation
Reason for alignment
Padding allows faster memory access i.e. for cpu, accessing memory areas that are aligned is faster e.g. reading a 4 byte aligned integer might take a single read call where as if an integer is located at a non aligned address range (say address 0x0002 - 0x0006), then it would take two memory reads to get this integer.
One way to force compiler to avoid alignment is (specific to gcc/g++) to use keyword 'packed' with the structure attribute. packed keyword Also the link specifies how to enforce alignment by a specific boundary of your choice (2, 4, 8 etc.) using the aligned keyword.
Best practice
It is always a good idea to structure your class/struct in a way that variables are already aligned with minimum padding. This reduces the size of the class overall plus it reduces the amount of work done by the compiler i.e. no rearrangement of structure. Also one should always access member variables by their names in the code, rather than trying to read a specific byte from structure assuming a value would be located at that byte.
Another useful SO question on performance advantage of alignment
For the sake of completion, following would still have a size of 8 bytes in your scenario (32 bit machine), but it won't get any better since full 8 bytes are now occupied, and there is no padding.
class temp
{
public:
int i;
short s;
char c;
char c2;
};
class temp
{
public:
int i; //size 4 alignment 4
short s; //size 2 alignment 2
char c; //size 1 alignment 1
}; //Size 8 alignment max(4,2,1)=4
temp[i[0-4];s[4-2];c[6-7]]] -> 8
Padding in (7-8)
class temp
{
public:
char c; //size 1 alignment 1
int i; //size 4 alignment 4
short s; //size 2 alignment 2
};//Size 12 alignment max(4,2,1)=4
temp[c[0-1];i[4-8];s[8-10]]] -> 12
Padding in (1-4) and (10-12)
Someone explain me how does the order of the member declaration inside a class determines the size of that class.
For Example :
class temp
{
public:
int i;
short s;
char c;
};
The size of above class is 8 bytes.
But when the order of the member declaration is changed as below
class temp
{
public:
char c;
int i;
short s;
};
then the size of class is 12 bytes.
How?
The reason behind above behavior is data structure alignment and padding. Basically if you are creating a 4 byte variable e.g. int, it will be aligned to a four byte boundary i.e. it will start from an address in memory, which is multiple of 4. Same applies to other data types. 2 byte short should start from even memory address and so on.
Hence if you have a 1 byte character declared before the int (assume 4 byte here), there will be 3 free bytes left in between. The common term used for them is 'padded'.
Data structure alignment
Another good pictorial explanation
Reason for alignment
Padding allows faster memory access i.e. for cpu, accessing memory areas that are aligned is faster e.g. reading a 4 byte aligned integer might take a single read call where as if an integer is located at a non aligned address range (say address 0x0002 - 0x0006), then it would take two memory reads to get this integer.
One way to force compiler to avoid alignment is (specific to gcc/g++) to use keyword 'packed' with the structure attribute. packed keyword Also the link specifies how to enforce alignment by a specific boundary of your choice (2, 4, 8 etc.) using the aligned keyword.
Best practice
It is always a good idea to structure your class/struct in a way that variables are already aligned with minimum padding. This reduces the size of the class overall plus it reduces the amount of work done by the compiler i.e. no rearrangement of structure. Also one should always access member variables by their names in the code, rather than trying to read a specific byte from structure assuming a value would be located at that byte.
Another useful SO question on performance advantage of alignment
For the sake of completion, following would still have a size of 8 bytes in your scenario (32 bit machine), but it won't get any better since full 8 bytes are now occupied, and there is no padding.
class temp
{
public:
int i;
short s;
char c;
char c2;
};
class temp
{
public:
int i; //size 4 alignment 4
short s; //size 2 alignment 2
char c; //size 1 alignment 1
}; //Size 8 alignment max(4,2,1)=4
temp[i[0-4];s[4-2];c[6-7]]] -> 8
Padding in (7-8)
class temp
{
public:
char c; //size 1 alignment 1
int i; //size 4 alignment 4
short s; //size 2 alignment 2
};//Size 12 alignment max(4,2,1)=4
temp[c[0-1];i[4-8];s[8-10]]] -> 12
Padding in (1-4) and (10-12)