pascal has always supported packed structures which are probably easiest explained using an example
Lets say you have two arrays x and y, and that we are using a 16 bit processor. That is, the 'word' size of the processor is 16 bits.
b : byte;
i : integer;
x : array[1..10] of myrec;
y : packed array[1..10] of myrec;
Pascal only tells you that you have 10 elements to work with, each holding a 3 bytes of information (lets assume integer is the old 16 bit variety).
It actually says nothing about how that information is stored.
You may assume the array is stored in 30 consecutive bytes, however this is not necessary true and is completely compiler dependent (a really good reason to avoid pointer mathematics).
A complier may well put a dummy byte in between the field values b and i, in order to ensure that both b and i fall on word boundaries.
In this instance the structure will take a total of 40 bytes.
The 'packed' reserved word instructs the compiler to optimise for size over speed, whereas leaving packed out, the compiler will generally optimise for speed over size.
In this case the structure would be optimised and could take only 30 bytes.
Again I say 'could' because it is still compiler dependent. The 'packed' keyword just says to pack the data closer together, but doesn't actually say how.
Some compilers therefore simply ignored the keyword, whereas others used packed to disable word alignment.
In the case of the latter, what typically could happen is that each element is aligned to the word size of the processor.
You need to realise here that the word size of the processor is typically the register size, not simply '16 bits' as it has commonly come to mean. In the case of a 32 bit processor for example the word size is 32 bits (even though we generically define words as 16 bits - this is just a historical throwback)
In a sense it is it the 'memory' equivalent of a disk sector.
By packing data, you could potentially have values such as integer crossing over word boundaries therefore requiring more memory manipulation (much like needing to read two disk sectors if a record crosses a sector boundary).
So basically what the change means, is the delphi is now fully using the packed keyword and forcing byte alignment (over word alignment) all of the time.
Hope this is enough to explain it. It is actually a bigger topic that I can reasonably answer in a few paragraphs.
UPDATE, continuation of comment thread below...
DavidH> I cannot imagine that you mean that the compiler is capable of producing different output given identical input
Yes David, that is exactly what I am saying. Not necessarily from one compile to the next on the same compiler, but certainly between versions of compiler, brands of compiler and different platforms.
TonyH > I think most of us always assumed packed = byte aligned, so now we are scratching our heads for a scenario where it doesn't. @David Heffernan is asking if anyone knows one
Tony, you have hit the nail on the head here.
You have assumed that packed works like a compiler directive that specifies how the data memory is organised.
This is not what it means. A better analogy is to consider the optimise directive for code generation.
You know the code is being optimised, but you don't necessarily specifically what the underlying outputted code will be, nor do you need to.
I can give you plenty of examples.
Lets say you have the following (I am using an array, it could apply just as easily to a record)
myarray = packed array[1..8] of boolean
If you then print a SizeOf(myarray) what would you expect?
The answer is that delphi does not guarantee that packed is implemented in any particular way.
So therefore the answer could be 8 bytes (if you are byte aligning each element).
It is just as valid for delphi to pack these as bits, and so the entire array could fit into 1 byte.
It could be 16 bytes if the compiler decides not to optimise on byte boundaries and is running on a 16 bit architecture.
Yes it would be less efficient in terms of speed, but the whole point of packing is to optimise for size over speed.
Whatever it does is invisible to the developer as long as they simply access the array elements and don't make any assumptions and try their own pointer mathematics to access the underlying data.
Similarly you cannot even guarantee the internal organisation of a primitive - it is platform dependent, not compiler dependent. E.g. If you have worked across multiple architectures you will be aware of issues surrounding how many bits make up an integer; whether or not the bytes within that integer are stored in byte order, or reverse byte order.
These types of architectural issues are exactly why various techniques such as comma delimited file, xml, etc have been developed. In order to provide a reliable common platform.
To summarise, David the issue is that you are actually asking the wrong question. If you consider the Embarcadero quote in the context of what I have said, you will see that it is consistent with what I am saying.