January 31, 2012 // 8:37 pm - Following up on his
status update for the PS3 4.0 Homebrew Enabler (HEN), today Sony PlayStation 3 hacker
KaKaRoToKS has explained how the ECDSA algorithm works.
To quote: To popular demand, I have decided to try and explain how the ECDSA algorithm works. I've been struggling a bit to understand it properly and while I found a lot of documentation about it, I haven't really found any "ECDSA for newbies" anywhere.
So I thought it would be good to explain in simple terms how it works so others can learn from my research. I have found some websites that explain the basic principles but nowhere near enough to actually understand it, others that explains things without any basics, making it incomprehensible, and others that go way too deep into the the mathematics behind it.
ECDSA stands for "Elliptic Curve Digital Signature Algorithm", it's used to create a digital signature of data (a file for example) in order to allow you to verify its authenticity without compromising its security. Think of it like a real signature, you can recognize someone's signature, but you can't forge it without others knowing.
The ECDSA algorithm is basically all about mathematics.. so I think it's important to start by saying : "hey kids, don't slack off at school, listen to your teachers, that stuff might be useful for you some day!"
But these maths are fairly complicated, so while I'll try to vulgarize it and make it understandable for non technical people, you will still probably need some knowledge in mathematics to understand it properly.
I will do this in two parts, one that is a sort of high level explanation about how it works, and another where I dig deeper into its inner workings to complete your understanding. Note however that I've just recently learned this stuff, so I'm definitely not an expert on the matter.
So the principle is simple, you have a mathematical equation which draws a curve on a graph, and you choose a random point on that curve and consider that your point of origin. Then you generate a random number, this is your private key, you do some magical mathematical equation using that random number and that "point of origin" and you get a second point on the curve, that's your public key. When you want to sign a file, you will use this private key (the random number) with a hash of the file (a unique number to represent the file) into a magical equation and that will give you your signature. The signature itself is divided into two parts, called R and S.
In order to verify that the signature is correct, you only need the public key (that point on the curve that was generated using the private key) and you put that into another magical equation with one part of the signature (S), and if it was signed correctly using the the private key, it will give you the other part of the signature (R). So to make it short, a signature consists of two numbers, R and S, and you use a private key to generate R and S, and if a mathematical equation using the public key and S gives you R, then the signature is valid. There is no way to know the private key or to create a signature using only the public key.
Alright, now for the more in depth understanding, I suggest you take an aspirin right now as this might hurt!
Let's start with the basics (which may be boring for people who know about it, but is mandatory for those who don't) : ECDSA uses only integer mathematics, there are no floating points (this means possible values are 1, 2, 3, etc.. but not 1.5..), also, the range of the numbers is bound by how many bits are used in the signature (more bits means higher numbers, means more security as it becomes harder to 'guess' the critical numbers used in the equation), as you should know, computers use 'bits' to represent data, a bit is a 'digit' in binary notation (0 and 1) and 8 bits represent one byte.
Every time you add one bit, the maximum number that can be represented doubles, with 4 bits you can represent values 0 to 15 (for a total of 16 possible values), with 5 bits, you can represent 32 values, with 6 bits, you can represent 64 values, etc.. one byte (8 bits) can represent 256 values, and 32 bits can represent 4294967296 values (4 Giga).. Usually ECDSA will use 160 bits total, so that makes well, a very huge number with 49 digits in it
ECDSA is used with a SHA1 cryptographic hash of the message to sign (the file). A hash is simply another mathematical equation that you apply on every byte of data which will give you a number that is unique to your data. Like for example, the sum of the values of all bytes may be considered a very dumb hash function.
So if anything changes in the message (the file) then the hash will be completely different. In the case of the SHA1 hash algorithm, it will always be 20 bytes (160 bits). It's very useful to validate that a file has not been modified or corrupted, you get the 20 bytes hash for a file of any size, and you can easily recalculate that hash to make sure it matches. What ECDSA signs is actually that hash, so if the data changes, the hash changes, and the signature isn't valid anymore.
Now, how does it work? Well Elliptic Curve cryptography is based on an equation of the form : y^2 = (x^3 + a * x + b) mod p
First thing you notice is that there is a modulo and that the 'y' is a square. This means that for any x coordinate, you will have two values of y and that the curve is symmetric on the X axis. The modulo is a prime number and makes sure that all the values are within our range of 160 bits and it allows the use of "modular square root" and "modular multiplicative inverse" mathematics which make calculating stuff easier (I think).
Since we have a modulo (p) , it means that the possible values of y^2 are between 0 and p-1, which gives us p total possible values. However, since we are dealing with integers, only a smaller subset of those values will be a "perfect square" (the square value of two integers), which gives us N possible points on the curve where N < p (N being the number of perfect squares between 0 and p). Since each x will yield two points (positive and negative values of the square-root of y^2), this means that there are N/2 possible 'x' coordinates that are valid and that give a point on the curve.
So this elliptic curve has a finite number of points on it, and it's all because of the integer calculations and the modulus. Another thing you need to know about Elliptic curves, is the notion of "point addition". It is defined as adding one point P to another point Q will lead to a point S such that if you draw a line from P to Q, it will intersect the curve on a third point R which is the negative value of S (remember that the curve is symmetric on the X axis). In this case, we define R = -S to represent the symmetrical point of R on the X axis. This is easier to illustrate with an image :
So you can see a curve of the form y^2 = x^3 + ax + b (where a = -4 and b = 0), which is symmetric on the X axis, and where P+Q is the symmetrical point through X of the point R which is the third intersection of a line going from P to Q. In the same manner, if you do P + P, it will be the symmetrical point of R which is the intersection of the line that is a tangent to the point P.. And P + P + P is the addition between the resulting point of P+P with the point P since P + P + P can be written as (P+P) + P.. This defines the "point multiplication" where k*P is the addition of the point P to itself k times here are two examples showing this :
Here, you can see two elliptic curves, and a point P from which you draw the tangent, it intersects the curve with a third point, and its symmetric point it 2P, then from there, you draw a line from 2P and P and it will intersect the curve, and the symmetrical point is 3P. etc you can keep doing that for the point multiplication. You can also already guess why you need to take the symmetric point of R when doing the addition, otherwise, multiple additions of the same point will always give the same line and the same three intersections.
One particularity of this point multiplication is that if you have a point R = k*P, where you know R and you know P, there is no way to find out what the value of 'k' is. Since there is no point subtraction or point division, you cannot just resolve k = R/P. Also, since you could be doing millions of point additions, you will just end up on another point on the curve, and you'd have no way of knowing "how" you got there. You can't reverse this operation, and you can't find the value 'k' which was multiplied with your point P to give you the resulting point R.
This thing where you can't find the multiplicand even when you know the original and destination points is the whole basis of the security behind the ECDSA algorithm, and the principle is called a "trap door function".
Now that we've handled the "basics", let's talk about the actual ECDSA signature algorithm. For ECDSA, you first need to know your curve parameters, those are a, b, p, N and G. You already know that 'a' and 'b' are the parameters of the curve function (y^2 = x^3 + ax + b), that 'p' is the prime modulus, and that 'N' is the number of points of the curve, but there is also 'G' that is needed for ECDSA, and it represents a 'reference point' or a point of origin if you prefer.
Those curve parameters are important and without knowing them, you obviously can't sign or verify a signature. Yes, verifying a signature isn't just about knowing the public key, you also need to know the curve parameters for which this public key is derived from.
So first of all, you will have a private and a public key.. the private key is a random number (of 20 bytes) that is generated, and the public key is a point on the curve generated from the point multiplication of G with the private key. We set 'dA' as the private key (random number) and 'Qa' as the public key (a point), so we have : Qa = dA * G (where G is the point of reference in the curve parameters).
So how do you sign a file/message ? First, you need to know that the signature is 40 bytes and is represented by two values of 20 bytes each, the first one is called R and the second one is called S.. so the pair (R, S) together is your ECDSA signature.. now here's how you can create those two values in order to sign a file.. first you must generate a random value 'k' (of 20 byes), and use point multiplication to calculate the point P=k*G. That point's x value will represent 'R'. Since the point on the curve P is represented by its (x, y) coordinates (each being 20 bytes long), you only need the 'x' value (20 bytes) for the signature, and that value will be called 'R'. Now all you need is the 'S' value.
To calculate S, you must make a SHA1 hash of the message, this gives you a 20 bytes value that you will consider as a very huge integer number and we'll call it 'z'. Now you can calculate S using the equation : S = k^-1 (z + dA * R) mod p
Note here the k^-1 which is the 'modular multiplicative inverse' of k it's basically the inverse of k, but since we are dealing with integer numbers, then that's not possible, so it's a number such that (k^-1 * k ) mod p is equal to 1. And again, I remind you that k is the random number used to generate R, z is the hash of the message to sign, dA is the private key and R is the x coordinate of k*G (where G is the point of origin of the curve parameters).
Now that you have your signature, you want to verify it, it's also quite simple, and you only need the public key (and curve parameters of course) to do that. You use this equation to calculate a point P : P= S^-1*z*G + S^-1 * R * Qa
If the x coordinate of the point P is equal to R, that means that the signature is valid, otherwise it's not.
Pretty simple, huh? now let's see why and how and this is going to require some mathematics to verify : We have :
P = S^-1*z*G + S^-1 * R *Qa
but Qa = dA*G, so:
P = S^-1*z*G + S^-1 * R * dA*G = S^-1 (z + dA* R) * G
But the x coordinate of P must match R and R is the x coordinate of k * G, which means that :
k*G = S^-1 (z + dA * R) *G
we can simplify by removing G which gives us :
k = S^-1(z + dA * R)
by inverting k and S, we get :
S = k^-1 (z + dA *R)
and that is the equation used to generate the signature.. so it matches, and that is the reason why you can verify the signature with it.
You can note that you need both 'k' (random number) and 'dA' (the private key) in order to calculate S, but you only need R and Qa (public key) to validate the signature. And since R=k*G and Qa = dA*G and because of the trap door function in the ECDSA point multiplication (explained above), we cannot calculate dA or k from knowing Qa and R, this makes the ECDSA algorithm secure, there is no way of finding the private keys, and there is no way of faking a signature without knowing the private key.
The ECDSA algorithm is used everywhere and has not been cracked and it is a vital part of most of today's security.
Now I'll discuss on how and why the ECDSA signatures that Sony used in the PS3 were faulty and how it allowed us to gain access to their private key.
So you remember the equations needed to generate a signature.. R = k*G and S= k^-1(z + dA*R) mod p.. well this equation's strength is in the fact that you have one equation with two unknowns (k and dA) so there is no way to determine either one of those.
However, the security of the algorithm is based on its implementation and it's important to make sure that 'k' is randomly generated and that there is no way that someone can guess, calculate, or use a timing attack or any other type of attack in order to find the random value 'k'. But Sony made a huge mistake in their implementation, they used the same value for 'k' everywhere, which means that if you have two signatures, both with the same k, then they will both have the same R value, and it means that you can calculate k using two S signatures of two files with hashes z and z' and signatures S and S' respectively :
S - S' = k^-1 (z + dA*R) - k^-1 (z' + da*R) = k^-1 (z + da*R - z' -dA*R) = k^-1 (z - z')
So : k = (z - z') / (S - S')
Once you know k, then the equation for S because one equation with one unknown and is then easily resolved for dA :
dA = (S*k - z) / R
Once you know the private key dA, you can now sign your files and the PS3 will recognize it as an authentic file signed by Sony. This is why it's important to make sure that the random number used for generating the signature is actually "cryptographically random". This is also the reason why it is impossible to have a custom firmware above 3.56, simply because since the 3.56 version, Sony have fixed their ECDSA algorithm implementation and used new keys for which it is impossible to find the private key.. if there was a way to find that key, then the security of every computer, website, system may be compromised since a lot of systems are relying on ECDSA for their security, and it is impossible to crack.
Finally! I hope this makes the whole algorithm clearer to many of you.. I know that this is still very complicated and hard to understand. I usually try to make things easy to understand for non technical people, but this algorithm is too complex to be able to explain in any simpler terms. After all that's why I prefer to call it the MFET algorithm (Mathematics For Extra Terrestrials)
But if you are a developer or a mathematician or someone interested in learning about this because you want to help or simple gain knowledge, then I'm sure that this contains enough information for you to get started or to at least understand the concept behind this unknown beast called "ECDSA".
That being said, I'd like to thank a few people who helped me understand all of this, one particularly who wishes to remain anonymous, as well as the many wikipedia pages I linked to throughout this article, and Avi Kak thanks to his
paper explaining the mathematics behind ECDSA, and from which I have taken those graph images aboves.
P.s: In this article, I used '20 bytes' in my text to talk about the ECDSA signature because that's what is usually used as it matches the SHA1 hash size of 20 bytes and that's what the PS3 security uses, but the algorithm itself can be used with any size of numbers. There may be other inaccuracies in this article, but like I said, I'm not an expert, I just barely learned all of this in the past week.
Yea sure and what about the 360 scene ? Is C4E (hail to you man) not working on piracy stuff ? Or all others they have made backups and a hacked con eg via gligli possible not working on piracy ?
The so called dev's in ps3 scene seems to have the EGO HOT syndrome. Hinting infos for them an not give out to the scene. Some one said they are afraid of that sony will patch the possibility of using the debugger as a mode for games and among other stuff when they release. Does the average user really believe this ?
Hell sony have developed this sys and know better then some one else in this stuck scene how it make those games work. So why hinting this infos ? = EGO HOT syndrome. Just to have it for them self and laughing about the scene or just for them self and how good they are.
I can't really say whats the reason for but for sure not in case of being afraid off that sony will patch it. If they want to patch then they do and not in case of it gets public released.
They patched things in past without something useable was released. Also nabnab got a message from some one not to be called here that he should stop his work. Yea sure we will stop only in case of this person tell us/him to do so.
On some points a lot of dev's in the ps3 scene think they are god's or better then the average user. We are all the same it's not a matter of the color of your skin and also it's not a matter if you're a normal user or a hacker or a coder, scriptor, modder or what ever.
We all deserve the same and no one have the right's to milk some one other with stuff that should be free.
Hail to grafchockolo and shame to the one that use his work to milk the average user and also shame to all others that hinting informations.
I know that i repeat many times Graf offer big stuff about the PS3, the only one who was thinking release public the work (a person recently contact me to tell me some interesting stuff about PS3dev wiki and other dev on the PS3 scene, that they like to keep secret or share work from other), even Sony offer the best door to exploit the PS3 but it look like that some devs prefer to make business with free stuff and after we ask why Sony make some bad action (actually i didn't see anyone going to the jail and it would never happen for that)
I know it's so annoying to wait something you are waiting for a long time but unfortunately some dev don't know the definition share and like to make business with that, also they make crappy code or steal code from other dev that share for free and put on a dongle with stupid drm to hide the crappy work and scared to see the PS3 users complaining about that.
You know i stop some my work not related to the PS3, just to come give help and i saw the last few weeks many insult from the PS3 users and even the PS Vita users lol, also see some dev good lie to distract the PS3 users and said don't trust him to hide the real information from different website of the PS3 hack, i saw some website respectful and other website that judge a person they don't even know and try to make some fire for nothing...
The Truth Behind the Lie
I always try to do my best to help people on the PC community, i make alternative driver, patch for games, mods... many of this work was released for free and i was working alone on it, i received so many thanks than i didn't expected that much and also some good insult... but the world is like that and you can't change it, you can make it better but don't change it .
I keep working and let you know all what i'm trying to do.
Considering your statements you won't have to get any keys and thus it's still possible to run homebrew/backups on PS3 FW >3.55 by bypassing any key requirements with "devtools".
Look like that nobody read the my post about a possible 4.0 alternative... also this is more a leave the scene and check somewhere else.
I'm packing my 3.55 in a corner, buying a new one soon, you never know. I'm not hoping anymore, it was obvious seeing the inertia of the scene that nothing was gonna happen for some time.
Maybe in a few years when PS4 will be here someone will find another way in.