# How to approach number guessing game(with a twist) algorithm?

I am learning programming (python and algo’s) and was trying to work on a project that I find interesting. I have created a few basic python scripts but I’m not sure how to approach a solution to a game I am trying to build.

Here’s how the game will work:

users will be given items with a value. For example

``````Apple = 1
Pears = 2
Oranges  = 3
``````

They will then get a chance to choose any combo of them they like (i.e. 100 apples, 20 pears, and 1 oranges). The only output the computer gets is the total value(in this example, its currently \$143). The computer will try to guess what they have. Which obviously it won’t be able to get correctly the first turn.

``````         Value  quantity(day1)  value(day1)
Apple    1      100             100
Pears    2      20              40
Orange   3      1               3
Total           121             143
``````

The next turn the user can modify their numbers but no more than 5% of the total quantity (or some other percent we may chose. I’ll use 5% for example.). The prices of fruit can change(at random) so the total value may change based on that also(for simplicity I am not changing fruit prices in this example). Using the above example, on day 2 of the game, the user returns a value of \$152 and \$164 on day 3. Here's an example.

``````quantity(day2)  %change(day2)   value(day2) quantity(day3)  %change(day3)   value(day3)
104                             104         106                             106
21                              42          23                              46
2                               6           4                               12
127             4.96%           152         133             4.72%           164
``````

*(I hope the tables show up right, I had to manually space them so hopefully its not just doing it on my screen, if it doesn't work let me know and I'll try to upload a screenshot).

I am trying to see if I can figure out what the quantities are over time(assuming the user will have the patience to keep entering numbers). I know right now my only restriction is the total value cannot be more than 5% so I cannot be within 5% accuracy right now so the user will be entering it forever.

What I have done so far

Here’s my solution so far(not much). Basically I take all the values and figure out all the possible combos of them(I am done this part). Then I take all the possible combos and put them in a database as a dictionary(so for example for \$143, there could be a dictionary entry {apple:143, Pears:0, Oranges :0}..all the way to {apple:0, Pears:1, Oranges :47}. I do this each time I get a new number so I have a list of all possibilities.

Here’s where I’m stuck. Is using the rules above, how can I figure out the best possible solution? I think I’ll need a fitness function that automatically compares the two days data and removes any possibilities that have more than 5% variance of the previous days data.

Questions:

So my question with user changing the total and me having a list of all the probabilities, how should I approach this? What do I need to learn? Is there any algorithms out there or theories that I can use that are applicable? Or, to help me understand my mistake, can you suggest what rules I can add to make this goal feasible(if its not in its current state. I was thinking adding more fruits and saying they must pick at least 3,etc..)? Also, I only have a vague understanding of genetic algorithms but I thought I could use them here, if is there something I can use?

I'm very very eager to learn so any advice or tips would be greatly appreciated(just please don't tell me this game is impossible).

UPDATE: Getting feedback that this is hard to solve. So I thought I'd add another condition to the game that won't interfere with what the player is doing(game stays the same for them) but everyday the value of the fruits change price(randomly). Would that make it easier to solve? Because within a 5% movement and certain fruit value changes, only a few combo's are probable over time. Day 1, anything is possible and getting a close enough range is almost impossible, but as the prices of fruits change and the user can only choose a 5% change, then shouldn't(over time) the range be narrow and narrow. In the above example, if prices are volatile enough I think I could brute force a solution that gave me a range to guess in, but I'm trying to figure out if there's a more elegant solution or other solutions to keep narrowing this range over time.

UPDATE2: After reading and asking around, I believe this is a hidden markov/Viterbi problem that tracks the changes in fruit prices as well as total sum(weighting the last data point the heaviest). I'm not sure how to apply the relationship though. I think this is the case and could be wrong but at the least I'm starting to suspect this is a some type of machine learning problem.

Update3: I am created a test case(with smaller numbers) and a generator to help automate the user generated data and I am trying to create a graph from it to see what's more likely. Here's the code, along with the total values and comments on what the users actually fruit quantities are.

``````#!/usr/bin/env python
import itertools

#Fruit price data
fruitPriceDay1 = {'Apple':1,'Pears':2,'Oranges':3}
fruitPriceDay2 = {'Apple':2,'Pears':3,'Oranges':4}
fruitPriceDay3 = {'Apple':2,'Pears':4,'Oranges':5}

#generate possibilities for testing(Warning..will not scale with large numbers)
def possibilityGenerator(target_sum, apple, pears, oranges):
allDayPossible = {}
counter = 1
apple_range = range(0, target_sum + 1, apple)
pears_range = range(0, target_sum + 1, pears)
oranges_range = range(0, target_sum + 1, oranges)
for i, j, k in itertools.product(apple_range, pears_range, oranges_range):
if i + j + k == target_sum:
currentPossible = {}
#print counter
#print 'Apple', ':', i/apple, ',', 'Pears', ':', j/pears, ',', 'Oranges', ':', k/oranges
currentPossible['apple'] = i/apple
currentPossible['pears'] = j/pears
currentPossible['oranges'] = k/oranges
#print currentPossible
allDayPossible[counter] = currentPossible
counter = counter +1
return allDayPossible

#total sum being returned by user for value of fruits
totalSumDay1=26 # computer does not know this but users quantities are apple: 20, pears 3, oranges 0 at the current prices of the day
totalSumDay2=51 # computer does not know this but users quantities are apple: 21, pears 3, oranges 0 at the current prices of the day
totalSumDay3=61 # computer does not know this but users quantities are apple: 20, pears 4, oranges 1 at the current prices of the day
graph = {}
graph['day1'] = possibilityGenerator(totalSumDay1, fruitPriceDay1['Apple'], fruitPriceDay1['Pears'], fruitPriceDay1['Oranges'] )
graph['day2'] = possibilityGenerator(totalSumDay2, fruitPriceDay2['Apple'], fruitPriceDay2['Pears'], fruitPriceDay2['Oranges'] )
graph['day3'] = possibilityGenerator(totalSumDay3, fruitPriceDay3['Apple'], fruitPriceDay3['Pears'], fruitPriceDay3['Oranges'] )
#sample of dict = 1 : {'oranges': 0, 'apple': 0, 'pears': 0}..70 : {'oranges': 8, 'apple': 26, 'pears': 13}
print graph
``````
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+1 for an excellent question which is clear and well formatted. – SpeedBirdNine Oct 8 '11 at 5:31
Thank you so much SpeedBirdNine. First time someone's said that to me here. Usually I get the exact opposite :-) – Lostsoul Oct 8 '11 at 5:33
You might want to try this on math.stackexchange.com – Ilmari Karonen Oct 8 '11 at 5:58
@Mysticial the points don't mean much to me but useful to draw more bright minds into attempting this problem. I think this problem's solution will benefit everyone in the community so I see it as totally worth it, if we all think of a solution and those reading end up with something useful in process. In the age of big data analytics and cheap cloud computing, I think these types of problems will grow and grow. Plus selfishly, I'm just interested in creating a program that friends/family will think is 'magic'! – Lostsoul Oct 10 '11 at 21:43
stats.stackexchange.com is more relevant than math. – cyborg Oct 19 '11 at 17:23

We'll combine graph-theory and probability:

On the 1st day, build a set of all feasible solutions. Lets denote the solutions set as A1={a1(1), a1(2),...,a1(n)}.

On the second day you can again build the solutions set A2.

Now, for each element in A2, you'll need to check if it can be reached from each element of A1 (given x% tolerance). If so - connect A2(n) to A1(m). If it can't be reached from any node in A1(m) - you can delete this node.

Basically we are building a connected directed acyclic graph.

All paths in the graph are equally likely. You can find an exact solution only when there is a single edge from Am to Am+1 (from a node in Am to a node in Am+1).

Sure, some nodes appear in more paths than other nodes. The probability for each node can be directly deduced based on the number of paths that contains this node.

By assigning a weight to each node, which equals to the number of paths that leads to this node, there is no need to keep all history, but only the previous day.

Also, have a look at non-negative-values linear diphantine equations - A question I asked a while ago. The accepted answer is a great way to enumarte all combos in each step.

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There is an extra reduction in the size of the sets possible. After your A1+A2 steps, if you add a next set of possible configurations A3, you can trim the sets A2 and A3 based on the "not reacheable within 5%" criterium, but you can also "cascade" this back to the A1-A2 junction. As a net result, the set A1 can only become smaller. But the set An+1 will "probably" be larger than the set An. But I don't think the aim of the gaim is to only guess the right candidate from the A1 set ... – wildplasser Oct 8 '11 at 17:44
@Lostsoul: If you find my answer unclear - please let me know and I'll try to explain better. – Lior Kogan Oct 13 '11 at 15:39
@LiorKogan I understand your solution but have been caught by trying to implement it successfully. I understand your logic and it makes sense, but I'm starting to think since all numbers have an equal probability of being successful, how can it differentiate the correct solution out of so many possibilities. I ended up looking into to the hidden markov model, which seems correct but it only weights the last successful match(not A1,A2,...). – Lostsoul Oct 14 '11 at 18:11
I'm not 100% sure still but I'm starting to think I'll need to use the hidden markov model to assign probabilities to the correct answer , then use a graph to navigate and try to find the best current answer(based on the history of total sums). What do you think? – Lostsoul Oct 14 '11 at 18:12
I don't suggest that all numbers are equally likely, but that all paths in the graph are equally likely. Some numbers (nodes) appear in more paths, hence they are more probable. The probability for each node can be calculated by dividing the number of paths (from t0) that goes through this node, by the total number of paths. *** Which part did you find hard to implement?" *** I wouldn't build a HMM here. There is no need to predict anything. We only need to infer our data and assign probabilities to each state. – Lior Kogan Oct 14 '11 at 19:04

This problem is impossible to solve. Lets say that you know exactly for what ratio number of items was increased, not just what is maximum ratio for this.

User has N fruits and you have D days of guessing.

In each day you get N new variables and then you have in total D*N variables.

For each day you can generate only 2 equations. One equation is sum of n_item*price and other is based on know ratio. In total you have at most 2*D equations if they are all independent.

2*D < N*D for all N > 2

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Thanks Ralu, someone on the math site said something simlair so I updated the question to add a new condition(without changing the process for the user). What if the value of the fruit changes randomly everyday(I would have no control over it, since I could easily put extreme values to isolate possibilities)? If fruits prices are changing, wouldn't certain possibilities be less likely and over time the possibilities actually decrease to something more accurate? – Lostsoul Oct 8 '11 at 15:59
There is no such thing as less an more probable. It is just about possible/impossible. And yes you can probably throw out some solutions if you know that they are integer solutions, but that is all. Think about that user begin whit 1000000, 1000000 and 1000000 and then it can change each value by +/- 50000 each time. So it does not matter if you limit difference for each step. – Luka Rahne Oct 8 '11 at 16:17
I agree with you and thank you for explaining. I'm just thinking there's two things I need to solve to get to the answer. One is to limit the possibilities. If the total value is 5 and the price of apples jumped to \$100 then clearly the user has no apples so I can eliminate that and so on..until maybe I have a range. Once I have that range then I think a simple guessing game structure can occur, the point of this question though is not to get the most accurate answer(which would be nice) but realistic how to get the most narrow range. – Lostsoul Oct 8 '11 at 16:52

Disclaimer: I changed my answer dramatically after temporarily deleting my answer and re-reading the question carefully as I misread some critical parts of the question. While still referencing similar topics and algorithms, the answer was greatly improved after I attempted to solve some of the problem in C# myself.

## Hollywood version

• The problem is a Dynamic constraint satisfaction problem (DCSP), a variation on Constraint satisfaction problems (CSP.)
• Use Monte Carlo to find potential solutions for a given day if values and quantity ranges are not tiny. Otherwise, use brute force to find every potential solutions.
• Use Constraint Recording (related to DCSP), applied in cascade to previous days to restrict the potential solution set.
• Cross your fingers, aim and shoot (Guess), based on probability.
• (Optional) Bruce Willis wins.

## Original version

First, I would like to state what I see two main problems here:

1. The sheer number of possible solutions. Knowing only the number of items and the total value, lets say 3 and 143 for example, will yield a lot of possible solutions. Plus, it is not easy to have an algorithm picking valid solution without inevitably trying invalid solutions (total not equal to 143.)

2. When possible solutions are found for a given day Di, one must find a way to eliminate potential solutions with the added information given by { Di+1 .. Di+n }.

Let's lay down some bases for the upcoming examples:

• Lets keep the same item values, the whole game. It can either be random or chosen by the user.
• The possible item values is bound to the very limited range of [1-10], where no two items can have the same value.
• No item can have a quantity greater than 100. That means: [0-100].

In order to solve this more easily I took the liberty to change one constraint, which makes the algorithm converge faster:

• The "total quantity" rule is overridden by this rule: You can add or remove any number of items within the [1-10] range, total, in one day. However, you cannot add or remove the same number of items, total, more than twice. This also gives the game a maximum lifecycle of 20 days.

This rule enables us to rule out solutions more easily. And, with non-tiny ranges, renders Backtracking algorithms still useless, just like your original problem and rules.

In my humble opinion, this rule is not the essence of the game but only a facilitator, enabling the computer to solve the problem.

### Problem 1: Finding potential solutions

For starters, problem 1. can be solved using a Monte Carlo algorithm to find a set of potential solutions. The technique is simple: Generate random numbers for item values and quantities (within their respective accepted range). Repeat the process for the required number of items. Verify whether or not the solution is acceptable. That means verifying if items have distinct values and the total is equal to our target total (say, 143.)

While this technique has the advantage of being easy to implement it has some drawbacks:

• The user's solution is not guaranteed to appear in our results.
• There is a lot of "misses". For instance, it takes more or less 3,000,000 tries to find 1,000 potential solutions given our constraints.
• It takes a lot of time: around 4 to 5 seconds on my lazy laptop.

How to get around these drawback? Well...

• Limit the range to smaller values and
• Find an adequate number of potential solutions so there is a good chance the user's solution appears in your solution set.
• Use heuristics to find solutions more easily (more on that later.)

Note that the more you restrict the ranges, the less useful while be the Monte Carlo algorithm is, since there will be few enough valid solutions to iterate on them all in reasonable time. For constraints { 3, [1-10], [0-100] } there is around 741,000,000 valid solutions (not constrained to a target total value.) Monte Carlo is usable there. For { 3, [1-5], [0-10] }, there is only around 80,000. No need to use Monte Carlo; brute force `for` loops will do just fine.

I believe the problem 1 is what you would call a Constraint satisfaction problem (or CSP.)

### Problem 2: Restrict the set of potential solutions

Given the fact that problem 1 is a CSP, I would go ahead and call problem 2, and the problem in general, a Dynamic CSP (or DCSP.)

[DCSPs] are useful when the original formulation of a problem is altered in some way, typically because the set of constraints to consider evolves because of the environment. DCSPs are viewed as a sequence of static CSPs, each one a transformation of the previous one in which variables and constraints can be added (restriction) or removed (relaxation).

One technique used with CSPs that might be useful to this problem is called Constraint Recording:

• With each change in the environment (user entered values for Di+1), find information about the new constraint: What are the possibly "used" quantities for the add-remove constraint.
• Apply the constraint to every preceding day in cascade. Rippling effects might significantly reduce possible solutions.

For this to work, you need to get a new set of possible solutions every day; Use either brute force or Monte Carlo. Then, compare solutions of Di to Di-1 and keep only solutions that can succeed to previous days' solutions without violating constraints.

You will probably have to keep an history of what solutions lead to what other solutions (probably in a directed graph.) Constraint recording enables you to remember possible add-remove quantities and rejects solutions based on that.

There is a lot of other steps that could be taken to further improve your solution. Here are some ideas:

• Record constraints for item-value combinations found in previous days solutions. Reject other solutions immediately (as item values must not change.) You could even find a smaller solution sets for each existing solution using solution-specific constraints to reject invalid solutions earlier.
• Generate some "mutant", full-history, solutions each day in order to "repair" the case where the D1 solution set doesn't contain the user's solution. You could use a genetic algorithm to find a mutant population based on an existing solution set.)
• Use heuristics in order find solutions easily (e.g. when a valid solution is found, try and find variations of this solution by substituting quantities around.)
• Use behavioral heuristics in order to predict some user actions (e.g. same quantity for every item, extreme patterns, etc.)
• Keep making some computations while the user is entering new quantities.

Given all of this, try and figure out a ranking system based on occurrence of solutions and heuristics to determine a candidate solution.

-
You should give a proof that it is NP-hard ... – Foo Bah Oct 10 '11 at 19:41
I will try to tomorrow, but I'm not too good at formal proofs. However, I can safely say that the problem looks like an optimisation problem, which is more often than not NP rather than P. – Bryan Menard Oct 11 '11 at 1:40
I finally removed the NP-hard assumption (and refactored my answer a great deal), since I initially though the problem was an optimization problem. The problem might still be of NP-something complexity, but I'm not certain. – Bryan Menard Oct 13 '11 at 19:48

I wrote a program to play the game. Of course, I had to automate the human side, but I believe I did it all in such a way that I shouldn't invalidate my approach when played against a real human.

I approached this from a machine learning perspective and treated the problem as a hidden markov model where the total price was the observation. My solution is to use a particle filter. This solution is written in Python 2.7 using NumPy and SciPy.

I stated any assumptions I made either explicitly in the comments or implicitly in the code. I also set some additional constraints for the sake of getting code to run in an automated fashion. It's not particularly optimized as I tried to err on the side comprehensibility rather than speed.

Each iteration outputs the current true quantities and the guess. I just pipe the output to a file so I can review it easily. An interesting extension would be to plot the output on a graph either 2D (for 2 fruits) or 3D (for 3 fruits). Then you would be able to see the particle filter hone in on the solution.

Update:

Edited the code to include updated parameters after tweaking. Included plotting calls using matplotlib (via pylab). Plotting works on Linux-Gnome, your mileage may vary. Defaulted NUM_FRUITS to 2 for plotting support. Just comment out all the pylab calls to remove plotting and be able to change NUM_FRUITS to anything.

Does a good job estimating the current fxn represented by UnknownQuantities X Prices = TotalPrice. In 2D (2 Fruits) this is a line, in 3D (3 Fruits) it'd be a plane. Seems to be too little data for the particle filter to reliably hone in on the correct quantities. Need a little more smarts on top of the particle filter to really bring together the historical information. You could try converting the particle filter to 2nd- or 3rd-order.

Update 2:

I've been playing around with my code, a lot. I tried a bunch of things and now present the final program that I'll be making (starting to burn out on this idea).

Changes:

The particles now use floating points rather than integers. Not sure if this had any meaningful effect, but it is a more general solution. Rounding to integers is done only when making a guess.

Plotting shows true quantities as green square and current guess as red square. Currently believed particles shown as blue dots (sized by how much we believe them). This makes it really easy to see how well the algorithm is working. (Plotting also tested and working on Win 7 64-bit).

Added parameters for turning off/on quantity changing and price changing. Of course, both 'off' is not interesting.

It does a pretty dang good job, but, as has been noted, it's a really tough problem, so getting the exact answer is hard. Turning off CHANGE_QUANTITIES produces the simplest case. You can get an appreciation for the difficulty of the problem by running with 2 fruits with CHANGE_QUANTITIES off. See how quickly it hones in on the correct answer then see how harder it is as you increase the number of fruit.

You can also get a perspective on the difficulty by keeping CHANGE_QUANTITIES on, but adjusting the MAX_QUANTITY_CHANGE from very small values (.001) to "large" values (.05).

One situation where it struggles is if on dimension (one fruit quantity) gets close to zero. Because it's using an average of particles to guess it will always skew away from a hard boundary like zero.

In general this makes a great particle filter tutorial.

``````from __future__ import division
import random
import numpy
import scipy.stats
import pylab

# Assume Guesser knows prices and total
# Guesser must determine the quantities

# All of pylab is just for graphing, comment out if undesired
#   Graphing only graphs first 2 FRUITS (first 2 dimensions)

NUM_FRUITS = 3
MAX_QUANTITY_CHANGE = .01 # Maximum percentage change that total quantity of fruit can change per iteration
MAX_QUANTITY = 100 # Bound for the sake of instantiating variables
MIN_QUANTITY_TOTAL = 10 # Prevent degenerate conditions where quantities all hit 0
MAX_FRUIT_PRICE = 1000 # Bound for the sake of instantiating variables
NUM_PARTICLES = 5000
NEW_PARTICLES = 500 # Num new particles to introduce each iteration after guessing
NUM_ITERATIONS = 20 # Max iterations to run
CHANGE_QUANTITIES = True
CHANGE_PRICES = True

'''
Change individual fruit quantities for a random amount of time
Never exceed changing fruit quantity by more than MAX_QUANTITY_CHANGE
'''
def updateQuantities(quantities):
old_total = max(sum(quantities), MIN_QUANTITY_TOTAL)
new_total = old_total
max_change = int(old_total * MAX_QUANTITY_CHANGE)

while random.random() > .005: # Stop Randomly
change_index = random.randint(0, len(quantities)-1)
change_val = random.randint(-1*max_change,max_change)

if quantities[change_index] + change_val >= 0: # Prevent negative quantities
quantities[change_index] += change_val
new_total += change_val

if abs((new_total / old_total) - 1) > MAX_QUANTITY_CHANGE:
quantities[change_index] -= change_val # Reverse the change

def totalPrice(prices, quantities):
return sum(prices*quantities)

def sampleParticleSet(particles, fruit_prices, current_total, num_to_sample):
# Assign weight to each particle using observation (observation is current_total)
# Weight is the probability of that particle (guess) given the current observation
# Determined by looking up the distance from the hyperplane (line, plane, hyperplane) in a
#   probability density fxn for a normal distribution centered at 0
variance = 2
distances_to_current_hyperplane = [abs(numpy.dot(particle, fruit_prices)-current_total)/numpy.linalg.norm(fruit_prices) for particle in particles]
weights = numpy.array([scipy.stats.norm.pdf(distances_to_current_hyperplane[p], 0, variance) for p in range(0,NUM_PARTICLES)])

weight_sum = sum(weights) # No need to normalize, as relative weights are fine, so just sample un-normalized

# Create new particle set weighted by weights
belief_particles = []
belief_weights = []
for p in range(0, num_to_sample):
sample = random.uniform(0, weight_sum)
# sum across weights until we exceed our sample, the weight we just summed is the index of the particle we'll use
p_sum = 0
p_i = -1
while p_sum < sample:
p_i += 1
p_sum += weights[p_i]
belief_particles.append(particles[p_i])
belief_weights.append(weights[p_i])

return belief_particles, numpy.array(belief_weights)

'''
Generates new particles around the equation of the current prices and total (better particle generation than uniformly random)
'''
def generateNewParticles(current_total, fruit_prices, num_to_generate):
new_particles = []
max_values = [int(current_total/fruit_prices[n]) for n in range(0,NUM_FRUITS)]
for p in range(0, num_to_generate):
new_particle = numpy.array([random.uniform(1,max_values[n]) for n in range(0,NUM_FRUITS)])
new_particle[-1] = (current_total - sum([new_particle[i]*fruit_prices[i] for i in range(0, NUM_FRUITS-1)])) / fruit_prices[-1]
new_particles.append(new_particle)
return new_particles

# Initialize our data structures:
# Represents users first round of quantity selection
fruit_prices = numpy.array([random.randint(1,MAX_FRUIT_PRICE) for n in range(0,NUM_FRUITS)])
fruit_quantities = numpy.array([random.randint(1,MAX_QUANTITY) for n in range(0,NUM_FRUITS)])
current_total = totalPrice(fruit_prices, fruit_quantities)
success = False

particles = generateNewParticles(current_total, fruit_prices, NUM_PARTICLES) #[numpy.array([random.randint(1,MAX_QUANTITY) for n in range(0,NUM_FRUITS)]) for p in range(0,NUM_PARTICLES)]
guess = numpy.average(particles, axis=0)
guess = numpy.array([int(round(guess[n])) for n in range(0,NUM_FRUITS)])

print "Truth:", str(fruit_quantities)
print "Guess:", str(guess)

pylab.ion()
pylab.draw()
pylab.scatter([p[0] for p in particles], [p[1] for p in particles])
pylab.scatter([fruit_quantities[0]], [fruit_quantities[1]], s=150, c='g', marker='s')
pylab.scatter([guess[0]], [guess[1]], s=150, c='r', marker='s')
pylab.xlim(0, MAX_QUANTITY)
pylab.ylim(0, MAX_QUANTITY)
pylab.draw()

if not (guess == fruit_quantities).all():
for i in range(0,NUM_ITERATIONS):
print "------------------------", i

if CHANGE_PRICES:
fruit_prices = numpy.array([random.randint(1,MAX_FRUIT_PRICE) for n in range(0,NUM_FRUITS)])

if CHANGE_QUANTITIES:
updateQuantities(fruit_quantities)
map(updateQuantities, particles) # Particle Filter Prediction

print "Truth:", str(fruit_quantities)
current_total = totalPrice(fruit_prices, fruit_quantities)

# Guesser's Turn - Particle Filter:
# Prediction done above if CHANGE_QUANTITIES is True

# Update
belief_particles, belief_weights = sampleParticleSet(particles, fruit_prices, current_total, NUM_PARTICLES-NEW_PARTICLES)
new_particles = generateNewParticles(current_total, fruit_prices, NEW_PARTICLES)

# Make a guess:
guess = numpy.average(belief_particles, axis=0, weights=belief_weights) # Could optimize here by removing outliers or try using median
guess = numpy.array([int(round(guess[n])) for n in range(0,NUM_FRUITS)]) # convert to integers
print "Guess:", str(guess)

pylab.cla()
#pylab.scatter([p[0] for p in new_particles], [p[1] for p in new_particles], c='y') # Plot new particles
pylab.scatter([p[0] for p in belief_particles], [p[1] for p in belief_particles], s=belief_weights*50) # Plot current particles
pylab.scatter([fruit_quantities[0]], [fruit_quantities[1]], s=150, c='g', marker='s') # Plot truth
pylab.scatter([guess[0]], [guess[1]], s=150, c='r', marker='s') # Plot current guess
pylab.xlim(0, MAX_QUANTITY)
pylab.ylim(0, MAX_QUANTITY)
pylab.draw()

if (guess == fruit_quantities).all():
success = True
break

# Attach new particles to existing particles for next run:
belief_particles.extend(new_particles)
particles = belief_particles
else:
success = True

if success:
print "Correct Quantities guessed"
else:
print "Unable to get correct answer within", NUM_ITERATIONS, "iterations"

pylab.ioff()
pylab.show()
``````
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wow..I was just going to write an answer to my own question saying that the answers were good but I think the solution is a hidden markov or viterbi algorithm. I got a message saying a new answer had been posted and I refreshed to this. Great answer. I'll do some tests and let you know how it goes..Thanks Kyle – Lostsoul Oct 13 '11 at 23:25
it seems interesting. I get your logic but there's a few questions I had. It seems like its randomly guessing. Is there a way to include not only the past sum but all of the past sums(with the last one more heavily weighted). It seems like every answer is close to the last answer only but looking a few sums back the result suggested doesn't seem related. – Lostsoul Oct 14 '11 at 3:13
It's only representing a first-order hidden markov model, so it's only caring about one step. An improvement would be to turn it into a 2nd or 3rd order. Right now I'm working on tuning the parameters for better results. In theory, a well-tuned 1st-order HMM should be fine, because the particles "represent" a history of where they came from. Hopefully I'll have a tuned update soon which works better. – Kyle Oct 14 '11 at 3:17
also my question is a bit different..but I am more trying to learn the algo for this. My question basically says based on the sum I compute a list of every possibility and wanted an algo to try to figure out which possibility was most likely. No worries though I think your logic applies, but I think somehow it needs to use the hidden markov or viterbi algorithm to track the changes in fruit prices as well as change in sum and based on that relation provide a guess. – Lostsoul Oct 14 '11 at 3:17
@Kyle..Thanks so much. I was asking on other boards questions of implementing and after reading your code, it did make things alot more clear. Getting it to go more than one order I think will be interesting, as my end goal is to give the user hundreds of options from a fictional store and let them choose any quantity(I will try to do this on hadoop and scale over my 3 machines at home, but the quicker it can figure it out the better). Thanks so much. – Lostsoul Oct 14 '11 at 3:21

For your initial rules : From my school years, I would say that if we make abstraction of the 5% changes, we have everyday an equation with 3 unknown values (sorry I don't know the maths vocabulary in english), which are the same values as previous day. At day 3, you have 3 equations, 3 unknown values, the solution should be direct.

I guess the 5% change each day may be forgotten if the values of the 3 elements are different enough, because, as you said, we will use approximations and round the numbers.

For your adapted rules : Too many unknown - and changing - values in this case, so there is no direct solution I know of. I would trust Lior on this, his approach looks fine! (if you have a limited range for prices and quantities)

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