Merge branch 'master' into adithya

.github/ISSUE_TEMPLATE/new-generator-idea.md

@@ -11,6 +11,6 @@ assignees: ''
 
 **Example Solution:**
 
-**Further explanation:**
+**Further explanation (optional):**
 
 **Would you like to be assigned to this:**

.github/workflows/python-publish.yml

@@ -1,5 +1,5 @@
 # This workflows will upload a Python Package using Twine when a release is created
-# For more information see: https://help.github.com/en/actions/language-and-framework-guides/using-python-with-github-actions#publishing-to-package-registries
+# For more information see https://help.github.com/en/actions/language-and-framework-guides/using-python-with-github-actions#publishing-to-package-registries
 
 name: Upload Python Package
 

.github/workflows/tests.yaml

@@ -9,15 +9,26 @@ jobs:
 
     steps:
     - uses: actions/checkout@v2
+
     - name: Set up Python
       uses: actions/setup-python@v2
       with:
         python-version: '3.x'
-    - name: Install dependencies
+
+    - uses: actions/cache@v1
+      with:
+        path: ~/.cache/pip
+        key: ${{ runner.os }}-pip-${{ hashFiles('**/dev-requirements.txt') }}
+        restore-keys: |
+          ${{ runner.os }}-pip-
+
+    - name: Install Dependencies
+      if: steps.cache.outputs.cache-hit != 'true'
       run: |
-        python -m pip install -U pip
+        pip install -r dev-requirements.txt
-        python -m pip install -r dev-requirements.txt
+
     - name: Linter
       run: make lint
+
     - name: Test
       run: make test

README.md

@@ -31,85 +31,96 @@ problem, solution = mathgen.genById(0)
 | Id   | Skill                             | Example problem    | Example Solution      | Function Name            |
 |------|-----------------------------------|--------------------|-----------------------|--------------------------|
 [//]: # list start
-| 0 | Addition | 16+3= | 19 | subtraction |
+| 0 | Addition | 42+24= | 66 | addition |
-| 1 | Subtraction | 96-17= | 79 | multiplication |
+| 1 | Subtraction | 3-0= | 3 | subtraction |
-| 2 | Multiplication | 48*1= | 48 | multiplicationFunc) |
+| 2 | Multiplication | 69*0= | 0 | multiplication |
-| 3 | Division | 83/97= | 0.8556701030927835 | division |
+| 3 | Division | 98/90= | 1.0888888888888888 | division |
-| 4 | Binary Complement 1s | 1110110111= | 0001001000 | binaryComplement1s |
+| 4 | Binary Complement 1s | 100= | 011 | binary_complement_1s |
-| 5 | Modulo Division | 91%53= | 38 | binaryComplement1sFunc) |
+| 5 | Modulo Division | 37%49= | 37 | modulo_division |
-| 6 | Square Root | sqrt(64)= | 8 | moduloDivision |
+| 6 | Square Root | sqrt(25)= | 5 | square_root |
-| 7 | Power Rule Differentiation | 6x^7 | 42x^6 | squareRoot |
+| 7 | Power Rule Differentiation | 3x^10 + 1x^10 + 3x^9 + 4x^3 + 8x^7 | 30x^9 + 10x^9 + 27x^8 + 12x^2 + 56x^6 | power_rule_differentiation |
-| 8 | Square | 5^2= | 25 | powerRuleDifferentiation |
+| 8 | Square | 6^2= | 36 | square |
-| 9 | LCM (Least Common Multiple) | LCM of 20 and 10 = | 20 | "(n*m)x^(m-1)", |
+| 9 | LCM (Least Common Multiple) | LCM of 8 and 12 = | 24 | lcm |
-| 10 | GCD (Greatest Common Denominator) | GCD of 16 and 20 =  | 4 | powerRuleDifferentiationFunc) |
+| 10 | GCD (Greatest Common Denominator) | GCD of 11 and 19 =  | 1 | gcd |
-| 11 | Basic Algebra | 9x + 10 = 10 | 0 | square |
+| 11 | Basic Algebra | 1x + 4 = 7 | 3 | basic_algebra |
-| 12 | Logarithm | log3(3) | 1 | lcm |
+| 12 | Logarithm | log2(64) | 6 | log |
-| 13 | Easy Division | 399/19 =  | 21 | lcmFunc) |
+| 13 | Easy Division | 240/15 =  | 16 | int_division |
-| 14 | Decimal to Binary | Binary of 99= | 1100011 | gcd |
+| 14 | Decimal to Binary | Binary of 46= | 101110 | decimal_to_binary |
-| 15 | Binary to Decimal | 011100 | 28 | "c", gcdFunc) |
+| 15 | Binary to Decimal | 110101 | 53 | binary_to_decimal |
-| 16 | Fraction Division | (6/8)/(4/7) | 21/16 | basicAlgebra |
+| 16 | Fraction Division | (3/5)/(6/10) | 1 | divide_fractions |
-| 17 | Integer Multiplication with 2x2 Matrix | 2 * [[3, 3], [6, 3]] =  | [[6,6],[12,6]] | basicAlgebraFunc) |
+| 17 | Integer Multiplication with 2x2 Matrix | 7 * [[6, 9], [0, 9]] =  | [[42,63],[0,63]] | multiply_int_to_22_matrix |
-| 18 | Area of Triangle | Area of triangle with side lengths: 11 11 17 =  | 59.348020186018 | log |
+| 18 | Area of Triangle | Area of triangle with side lengths: 18 12 5 =  | (1.5018315853130168e-15+24.526771087935728j) | area_of_triangle |
-| 19 | Triangle exists check | Does triangle with sides 23, 29 and 34 exist? | Yes | intDivision |
+| 19 | Triangle exists check | Does triangle with sides 43, 37 and 16 exist? | Yes | valid_triangle |
-| 20 | Midpoint of the two point | (0,-20),(14,-16)= | (7.0,-18.0) | decimalToBinary |
+| 20 | Midpoint of the two point | (0,10),(3,-19)= | (1.5,-4.5) | midpoint_of_two_points |
-| 21 | Factoring Quadratic | x^2-5x-36 | (x-9)(x+4) | DecimalToBinaryFunc) |
+| 21 | Factoring Quadratic | x^2+4x-5 | (x+5)(x-1) | factoring |
-| 22 | Third Angle of Triangle | Third angle of triangle with angles 32 and 60 =  | 88 | binaryToDecimal |
+| 22 | Third Angle of Triangle | Third angle of triangle with angles 37 and 88 =  | 55 | third_angle_of_triangle |
-| 23 | Solve a System of Equations in R^2 | 4x - 6y = 14, -7x - 2y = 88 | x = -10, y = -9 | BinaryToDecimalFunc) |
+| 23 | Solve a System of Equations in R^2 | -4x - 7y = -63, x - y = 2 | x = 7, y = 5 | system_of_equations |
-| 24 | Distance between 2 points | Find the distance between (14, -9) and (12, 13) | sqrt(488) | fractionDivision |
+| 24 | Distance between 2 points | Find the distance between (18, -18) and (14, 0) | sqrt(340) | distance_two_points |
-| 25 | Pythagorean Theorem | The hypotenuse of a right triangle given the other two lengths 13 and 1 =  | 13.04 | divideFractionsFunc) |
+| 25 | Pythagorean Theorem | The hypotenuse of a right triangle given the other two lengths 3 and 14 =  | 14.32 | pythagorean_theorem |
-| 26 | Linear Equations | -12x + 13y = -22
+| 26 | Linear Equations | -20x + 5y = 200, 3x + -1y = -32 | x = -8, y = 8 | linear_equations |
--1x + -7y = -18 | x = 4, y = 2 | intMatrix22Multiplication |
+| 27 | Prime Factorisation | Find prime factors of 70 | [2, 5, 7] | prime_factors |
-| 27 | Prime Factorisation | Find prime factors of 2 | [2] | 17, "k * [[a,b],[c,d]] |
+| 28 | Fraction Multiplication | (8/3)*(8/4) | 16/3 | fraction_multiplication |
-| 28 | Fraction Multiplication | (8/6)*(4/10) | 8/15 | "[[k*a,k*b],[k*c,k*d]]", |
+| 29 | Angle of a Regular Polygon | Find the angle of a regular polygon with 19 sides | 161.05 | angle_regular_polygon |
-| 29 | Angle of a Regular Polygon | Find the angle of a regular polygon with 11 sides | 147.27 | multiplyIntToMatrix22) |
+| 30 | Combinations of Objects | Number of combinations from 14 objects picked 9 at a time  | 2002 | combinations |
-| 30 | Combinations of Objects | Number of combinations from 15 objects picked 7 at a time  | 6435 | areaOfTriangle |
+| 31 | Factorial | 2! =  | 2 | factorial |
-| 31 | Factorial | 3! =  | 6 | "Area of Triangle with side lengths a, b, c |
+| 32 | Surface Area of Cube | Surface area of cube with side = 6m is | 216 m^2 | surface_area_cube |
-| 32 | Surface Area of Cube | Surface area of cube with side = 14m is | 1176 m^2 | "area", areaOfTriangleFunc) |
+| 33 | Surface Area of Cuboid | Surface area of cuboid with sides = 6m, 19m, 8m is | 628 m^2 | surface_area_cuboid |
-| 33 | Surface Area of Cuboid | Surface area of cuboid with sides = 17m, 7m, 10m is | 718 m^2 | doesTriangleExist |
+| 34 | Surface Area of Cylinder | Surface area of cylinder with height = 35m and radius = 4m is | 980 m^2 | surface_area_cylinder |
-| 34 | Surface Area of Cylinder | Surface area of cylinder with height = 36m and radius = 7m is | 1891 m^2 | "Does triangle with sides a, b and c exist?", |
+| 35 | Volum of Cube | Volume of cube with side = 6m is | 216 m^3 | volume_cube |
-| 35 | Volum of Cube | Volume of cube with side = 10m is | 1000 m^3 | "Yes/No", isTriangleValidFunc) |
+| 36 | Volume of Cuboid | Volume of cuboid with sides = 16m, 8m, 7m is | 896 m^3 | volume_cuboid |
-| 36 | Volume of Cuboid | Volume of cuboid with sides = 20m, 17m, 4m is | 1360 m^3 | midPointOfTwoPoint |
+| 37 | Volume of cylinder | Volume of cylinder with height = 37m and radius = 16m is | 29757 m^3 | volume_cylinder |
-| 37 | Volume of cylinder | Volume of cylinder with height = 13m and radius = 1m is | 40 m^3 | "((X1,Y1),(X2,Y2)) |
+| 38 | Surface Area of cone | Surface area of cone with height = 5m and radius = 11m is | 797 m^2 | surface_area_cone |
-| 38 | Surface Area of cone | Surface area of cone with height = 17m and radius = 9m is | 798 m^2 | MidPointOfTwoPointFunc) |
+| 39 | Volume of cone | Volume of cone with height = 50m and radius = 13m is | 8848 m^3 | volume_cone |
-| 39 | Volume of cone | Volume of cone with height = 15m and radius = 5m is | 392 m^3 | factoring |
+| 40 | Common Factors | Common Factors of 93 and 71 =  | [1] | common_factors |
-| 40 | Common Factors | Common Factors of 69 and 51 =  | [1, 3] | "(x-x1)(x-x2)", factoringFunc) |
+| 41 | Intersection of Two Lines | Find the point of intersection of the two lines: y = -1/5x - 3 and y = -4/6x - 10 | (-15, 0) | intersection_of_two_lines |
-| 41 | Intersection of Two Lines | Find the point of intersection of the two lines: y = 6/3x + 9 and y = 6x + 2 | (7/4, 25/2) | thirdAngleOfTriangle |
+| 42 | Permutations | Number of Permutations from 14 objects picked 4 at a time =   | 24024 | permutation |
-| 42 | Permutations | Number of Permutations from 14 objects picked 1 at a time =   | 14 | "Third Angle of the triangle |
+| 43 | Cross Product of 2 Vectors | [4, 7, -12] X [5, -9, -17] =  | [-227, 8, -71] | vector_cross |
-| 43 | Cross Product of 2 Vectors | [19, 17, -9] X [10, -10, -2] =  | [-124, -52, -360] | thirdAngleOfTriangleFunc) |
+| 44 | Compare Fractions | Which symbol represents the comparison between 4/6 and 10/9? | < | compare_fractions |
-| 44 | Compare Fractions | Which symbol represents the comparison between 10/6 and 10/8? | > | systemOfEquations |
+| 45 | Simple Interest | Simple interest for a principle amount of 9253 dollars, 9% rate of interest and for a time period of 5 years is =  | 4163.85 | simple_interest |
-| 45 | Simple Interest | Simple interest for a principle amount of 7091 dollars, 10% rate of interest and for a time period of 4 years is =  | 2836.4 | "2x + 5y |
+| 46 | Multiplication of two matrices | Multiply<table><tr><td>2</td><td>0</td><td>1</td><td>10</td></tr><tr><td>5</td><td>-8</td><td>-7</td><td>5</td></tr><tr><td>3</td><td>1</td><td>-7</td><td>-6</td></tr><tr><td>6</td><td>10</td><td>4</td><td>-1</td></tr></table>and<table><tr><td>-4</td><td>1</td><td>-2</td></tr><tr><td>-10</td><td>-2</td><td>9</td></tr><tr><td>-4</td><td>-1</td><td>-5</td></tr><tr><td>-5</td><td>5</td><td>-8</td></tr></table> | <table><tr><td>-62</td><td>51</td><td>-89</td></tr><tr><td>63</td><td>53</td><td>-87</td></tr><tr><td>36</td><td>-22</td><td>86</td></tr><tr><td>-135</td><td>-23</td><td>66</td></tr></table> | matrix_multiplication |
-| 46 | Multiplication of two matrices | Multiply<table><tr><td>2</td><td>8</td><td>-4</td><td>5</td></tr><tr><td>6</td><td>-5</td><td>-6</td><td>4</td></tr></table>and<table><tr><td>-5</td><td>1</td><td>-3</td><td>2</td></tr><tr><td>5</td><td>8</td><td>5</td><td>-5</td></tr><tr><td>-6</td><td>-8</td><td>-6</td><td>-7</td></tr><tr><td>-1</td><td>-5</td><td>3</td><td>-7</td></tr></table> | <table><tr><td>49</td><td>73</td><td>73</td><td>-43</td></tr><tr><td>-23</td><td>-6</td><td>5</td><td>51</td></tr></table> | systemOfEquationsFunc) |
+| 47 | Cube Root | cuberoot of 556 upto 2 decimal places is: | 8.22 | cube_root |
-| 47 | Cube Root | cuberoot of 951 upto 2 decimal places is: | 9.83 | distance2Point |
+| 48 | Power Rule Integration | 2x^3 + 4x^3 | (2/3)x^4 + (4/3)x^4 + c | power_rule_integration |
-| 48 | Power Rule Integration | 10x^1 + 10x^6 + 1x^4 + 1x^6 | (10/1)x^2 + (10/6)x^7 + (1/4)x^5 + (1/6)x^7 + c | "Find the distance between (x1,y1) and (x2,y2)", |
+| 49 | Fourth Angle of Quadrilateral | Fourth angle of quadrilateral with angles 69 , 60, 101 = | 130 | fourth_angle_of_quadrilateral |
-| 49 | Fourth Angle of Quadrilateral | Fourth angle of quadrilateral with angles 15 , 191, 94 = | 60 | "sqrt(distanceSquared)", distanceTwoPointsFunc) |
+| 50 | Quadratic Equation | Zeros of the Quadratic Equation 91x^2+183x+84=0 | [-0.71, -1.3] | quadratic_equation |
-| 50 | Quadratic Equation | Zeros of the Quadratic Equation 48x^2+119x+57=0 | [-0.65, -1.83] | pythagoreanTheorem |
+| 51 | HCF (Highest Common Factor) | HCF of 4 and 16 =  | 4 | hcf |
-| 51 | HCF (Highest Common Factor) | HCF of 5 and 18 =  | 1 | "Pythagorean Theorem", 25, |
+| 52 | Probability of a certain sum appearing on faces of dice | If 2 dice are rolled at the same time, the probability of getting a sum of 11 = | 2/36 | dice_sum_probability |
-| 52 | Probability of a certain sum appearing on faces of dice | If 1 dice are rolled at the same time, the probability of getting a sum of 2 = | 1/6 | "The hypotenuse of a right triangle given the other two lengths a and b |
+| 53 | Exponentiation | 7^1 = | 7 | exponentiation |
-| 53 | Exponentiation | 17^7 = | 410338673 | "hypotenuse", pythagoreanTheoremFunc) |
+| 54 | Confidence interval For sample S | The confidence interval for sample [203, 201, 267, 239, 272, 283, 281, 298, 207, 265, 204, 261, 243, 235, 270, 284, 230, 222, 285, 266] with 80% confidence is | (259.5540983014814, 242.04590169851858) | confidence_interval |
-| 54 | Confidence interval For sample S | The confidence interval for sample [247, 230, 236, 207, 226, 278, 221, 297, 280, 267, 240, 259, 291, 284, 242, 252, 257, 220, 260, 213, 294] with 90% confidence is | (262.13973862175516, 242.71740423538768) | # This has multiple variables whereas #23 has only x and y |
+| 55 | Comparing surds | Fill in the blanks 73^(1/8) _ 4^(1/5) | > | surds_comparison |
-| 55 | Comparing surds | Fill in the blanks 17^(1/2) _ 3^(1/6) | > | linearEquations |
+| 56 | Fibonacci Series | The Fibonacci Series of the first 17 numbers is ? | [0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987] | fibonacci_series |
-| 56 | Fibonacci Series | The Fibonacci Series of the first 14 numbers is ? | [0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233] | "x |
+| 57 | Trigonometric Values | What is tan(90)? | ∞ | basic_trigonometry |
-| 57 | Trigonometric Values | What is sin(90)? | 1 | primeFactors |
+| 58 | Sum of Angles of Polygon | Sum of angles of polygon with 9 sides =  | 1260 | sum_of_polygon_angles |
-| 58 | Sum of Angles of Polygon | Sum of angles of polygon with 7 sides =  | 900 | "[b, c, d, ...]", primeFactorsFunc) |
+| 59 | Mean,Standard Deviation,Variance | Find the mean,standard deviation and variance for the data[35, 27, 43, 8, 30, 14, 16, 35, 29, 17, 6, 19, 5, 34, 40] | The Mean is 23.866666666666667 , Standard Deviation is 147.18222222222218, Variance is 12.13186804338978 | data_summary |
-| 59 | Mean,Standard Deviation,Variance | Find the mean,standard deviation and variance for the data[10, 47, 7, 37, 22, 44, 9, 30, 37, 8, 50, 29, 19, 12, 37] | The Mean is 26.533333333333335 , Standard Deviation is 214.38222222222217, Variance is 14.641797096744039 | fractionMultiplication |
+| 60 | Surface Area of Sphere | Surface area of Sphere with radius = 20m is | 5026.548245743669 m^2 | surface_area_sphere |
-| 60 | Surface Area of Sphere | Surface area of Sphere with radius = 6m is | 452.3893421169302 m^2 | "(a/b)*(c/d) |
+| 61 | Volume of Sphere | Volume of sphere with radius 48 m =  | 463246.68632773653 m^3 | volume_sphere |
-| 61 | Volume of Sphere | Volume of sphere with radius 54 m =  | 659583.6608064842 m^3 | multiplyFractionsFunc) |
+| 62 | nth Fibonacci number | What is the 59th Fibonacci number? | 956722026041 | nth_fibonacci_number |
-| 62 | nth Fibonacci number | What is the 5th Fibonacci number? | 5 | angleRegularPolygon |
+| 63 | Profit or Loss Percent | Loss percent when CP = 992 and SP = 888 is:  | 10.483870967741936 | profit_loss_percent |
-| 63 | Profit or Loss Percent | Loss percent when CP = 801 and SP = 230 is:  | 71.28589263420724 | "Angle of a Regular Polygon", 29, |
+| 64 | Binary to Hexidecimal | 1001 | 0x9 | binary_to_hex |
-| 64 | Binary to Hexidecimal | 101111 | 0x2f | "Find the angle of a regular polygon with 6 sides", "120", |
+| 65 | Multiplication of 2 complex numbers | (6+5j) * (19-20j) =  | (214-25j) | multiply_complex_numbers |
-| 65 | Multiplication of 2 complex numbers | (1+19j) * (-5+10j) =  | (-195-85j) | regularPolygonAngleFunc) |
+| 66 | Geometric Progression | For the given GP [10, 70, 490, 3430, 24010, 168070] ,Find the value of a,common ratio,6th term value, sum upto 11th term | The value of a is 10, common ratio is 7 , 6th term is 168070 , sum upto 11th term is 3295544570.0 | geometric_progression |
-| 66 | Geometric Progression | For the given GP [8, 88, 968, 10648, 117128, 1288408] ,Find the value of a,common ratio,11th term value, sum upto 8th term | The value of a is 8, common ratio is 11 , 11th term is 207499396808 , sum upto 8th term is 171487104.0 | combinations |
+| 67 | Geometric Mean of N Numbers | Geometric mean of 2 numbers 41 and 89 =  | (41*89)^(1/2) = 60.40695324215582 | geometric_mean |
-| 67 | Geometric Mean of N Numbers | Geometric mean of 2 numbers 9 and 18 =  | (9*18)^(1/2) = 12.727922061357855 | "Combinations of Objects", 30, |
+| 68 | Harmonic Mean of N Numbers | Harmonic mean of 4 numbers 69 , 15 , 41 , 67 =  |  4/((1/69) + (1/15) + (1/41) + (1/67)) = 33.20189882286996 | harmonic_mean |
-| 68 | Harmonic Mean of N Numbers | Harmonic mean of 2 numbers 59 and 8 =  |  2/((1/59) + (1/8)) = 14.08955223880597 | "Combinations available for picking 4 objects at a time from 6 distinct objects |
+| 69 | Euclidian norm or L2 norm of a vector | Euclidian norm or L2 norm of the vector[956.6848004224083, 711.3170367487223, 320.15804509062485, 424.1248983996525, 721.5190124346516, 94.2612318602214, 995.8301076180039, 80.46895520905917, 797.0886057296584, 923.9911613599512, 511.29812416326956, 358.730114740062, 2.3571520022257486, 218.67122157401798, 506.1431432680296, 413.8900730468059] is: | 2363.4212638753684 | euclidian_norm |
-| 69 | Euclidian norm or L2 norm of a vector | Euclidian norm or L2 norm of the vector[868.2223524505417, 443.64852085459694, 828.1090462421802] is: | 1279.217986044348 | " 15", combinationsFunc) |
+| 70 | Angle between 2 vectors | angle between the vectors [232.30943307265463, 306.39298862783016, 623.8368964487579, 808.2182550343807, 837.7902135238608, 194.4689016385932, 369.28549948572345] and [951.1858436627766, 293.2247329611225, 274.2885808744876, 590.5739827721277, 148.45211877240538, 867.5139830165438, 563.3907757868716] is: | NaN | angle_btw_vectors |
-| 70 | Angle between 2 vectors | angle between the vectors [47.34750277983446, 802.0548522330859, 163.10760759590525, 544.7736923139344, 595.2668887448631, 781.8577226989729, 505.92984665962115, 212.21898772758718, 417.09503653850567, 498.8451357914803, 216.11050052884383, 316.85172611004697, 531.4467890864679] and [551.4845648456056, 524.0267675199452, 252.30514761182056, 256.4954536977715, 423.09002486817883, 861.6683390714214, 210.90265341510906, 918.3205871874211, 539.9315722140092, 988.4812675617247, 885.1803007416202, 566.6430154592439, 851.2210274645834] is: | NaN | factorial |
+| 71 | Absolute difference between two numbers | Absolute difference between numbers 24 and 42 =  | 18 | absolute_difference |
-| 71 | Absolute difference between two numbers | Absolute difference between numbers 51 and 3 =  | 48 | surfaceAreaCubeGen |
+| 72 | Dot Product of 2 Vectors | [-8, 10, 0] . [20, 15, -17] =  | -10 | vector_dot |
-| 72 | Dot Product of 2 Vectors | [4, 20, 12] . [15, 11, 9] =  | 388 | "Surface area of cube with side a units is", |
+| 73 | Binary 2's Complement | 2's complement of 1110011110 = | 1100010 | binary_2s_complement |
-| 73 | Binary 2's Complement | 2's complement of 1 = | 1 | "b units^2", surfaceAreaCube) |
+| 74 | Inverse of a Matrix | Inverse of Matrix Matrix([[32, 97, 28], [31, 73, 53], [42, 33, 47]]) is: | Matrix([[1682/71213, -3635/71213, 3097/71213], [769/71213, 328/71213, -828/71213], [-2043/71213, 3018/71213, -671/71213]]) | invert_matrix |
-| 74 | Inverse of a Matrix | Inverse of Matrix Matrix([[2, 25, 60], [29, 30, 28], [23, 73, 95]]) is: | Matrix([[806/34457, 2005/34457, -1100/34457], [-2111/34457, -1190/34457, 1684/34457], [1427/34457, 429/34457, -665/34457]]) | surfaceAreaCuboidGen |
+| 75 | Area of a Sector | Given radius, 4 and angle, 17. Find the area of the sector. | Area of sector = 2.37365 | sector_area |
-| 75 | Area of a Sector | Given radius, 28 and angle, 317. Find the area of the sector. | Area of sector = 2168.81594 | "Surface Area of Cuboid", 33, |
+| 76 | Mean and Median | Given the series of numbers [83, 16, 72, 60, 34, 73, 3, 68, 31, 79]. find the arithmatic mean and mdian of the series | Arithmetic mean of the series is 51.9 and Arithmetic median of this series is 64.0 | mean_median |
-| 76 | Mean and Median | Given the series of numbers [67, 33, 40, 90, 81, 12, 91, 80, 5, 66]. find the arithmatic mean and mdian of the series | Arithmetic mean of the series is 56.5 and Arithmetic median of this series is 66.5 | "Surface area of cuboid with sides |
+| 77 | Determinant to 2x2 Matrix | Det([[88, 47], [82, 8]]) =  |  -3150 | int_matrix_22_determinant |
-| 77 | Determinant to 2x2 Matrix | Det([[10, 0], [95, 32]]) =  |  320 | "d units^2", surfaceAreaCuboid) |
+| 78 | Compound Interest | Compound interest for a principle amount of 2841 dollars, 7% rate of interest and for a time period of 5 year is =  | 3984.65 | compound_interest |
-| 78 | Compound Interest | Compound Interest for a principle amount of 4156 dollars, 8% rate of interest and for a time period of 7 compounded monthly is =  | 4156.0 | surfaceAreaCylinderGen |
+| 79 | Decimal to Hexadecimal | Binary of 756= | 0x2f4 | decimal_to_hexadeci |
-| 79 | Decimal to Hexadecimal | Binary of 143= | 0x8f | "Surface Area of Cylinder", 34, |
+| 80 | Percentage of a number | What is 32% of 78? | Required percentage = 24.96% | percentage |
-| 80 | Percentage of a number | What is 49% of 13? | Required percentage = 6.37% | "Surface area of cylinder with height |
+| 81 | Celsius To Fahrenheit | Convert 63 degrees Celsius to degrees Fahrenheit = | 145.4 | celsius_to_fahrenheit |
+| 82 | AP Term Calculation | Find the term number 41 of the AP series: -52, -109, -166 ...  | -2332 | arithmetic_progression_term |
+| 83 | AP Sum Calculation | Find the sum of first 21 terms of the AP series: -29, 47, 123 ...  | 15351.0 | arithmetic_progression_sum |
+| 84 | Converts decimal to octal | The decimal number 4008 in Octal is:  | 0o7650 | decimal_to_octal |
+| 85 | Converts decimal to Roman Numerals | The number 2529 in Roman Numerals is:  | MMDXXIX | decimal_to_roman_numerals |
+| 86 | Degrees to Radians | Angle 174 in radians is =  | 3.04 | degree_to_rad |
+| 87 | Radians to Degrees | Angle 2 in degrees is =  | 114.59 | radian_to_deg |
+| 88 | Differentiation | differentiate w.r.t x : d(sec(x)+6*x^(-2))/dx | tan(x)*sec(x) - 12/x^3 | differentiation |
+| 89 | Definite Integral of Quadratic Equation | The definite integral within limits 0 to 1 of the equation 5x^2 + 58x + 38 is =  | 68.6667 | definite_integral |
+| 90 | isprime | 83 | True | is_prime |
+| 91 | Binary Coded Decimal to Integer | Integer of Binary Coded Decimal 2 is =  | 9224 | bcd_to_decimal |
+| 92 | Complex To Polar Form | rexp(itheta) =  | 27.59exp(i0.81) | complex_to_polar |

dev-requirements.txt

@@ -4,3 +4,4 @@ flake8
 autopep8
 sympy
 numpy
+scipy

makeReadme.py

@@ -1,7 +1,6 @@
-# To use, paste at bottom of mathgen.py code, change line variable and remove all table rows in README.md except for the top 2 and run mathgen.py
-# NOTE: not anymore. but still leaving this comment in.
 from mathgenerator.mathgen import *
 
+
 def array2markdown_table(string):
     string = string.replace("[[", "<table><tr><td>")
     string = string.replace("[", "<tr><td>")
@@ -19,8 +18,6 @@ with open('mathgenerator/mathgen.py', 'r') as f:
     lines = f.readlines()
 
 allRows = []
-# get the first line of the functions in mathgen.py
-line = lines.index('# Funcs_start - DO NOT REMOVE!\n') + 1
 for item in wList:
     myGen = item[2]
     # NOTE: renamed 'sol' to 'solu' to make it look nicer
@@ -29,20 +26,16 @@ for item in wList:
     solu = str(solu).rstrip("\n")
     # edge case for matrixMultiplication
     if item[0] == 46:
-        prob, solu = myGen(10, 4)
+        prob, solu = myGen(maxVal=10, max_dim=4)
         prob = str(prob).rstrip("\n")
         solu = str(solu).rstrip("\n")
         prob = array2markdown_table(prob)
         solu = array2markdown_table(solu)
 
-    instName = lines[line]
     # NOTE: renamed 'def_name' to 'func_name' because it suits it more
-    func_name = instName[:instName.find('=')].strip()
+    func_name = item[3]
     row = [myGen.id, myGen.title, prob, solu, func_name]
     print('added', item[1], '-', func_name, 'to the README.md')
-    line += 1
-    if line > len(lines):
-        break
     allRows.append(row)
 
 with open('README.md', "r") as g:

mathgenerator/__init__.py

@@ -1,3 +1,5 @@
+import sys
+import traceback
 genList = []
 
 
@@ -8,15 +10,20 @@ class Generator:
         self.generalProb = generalProb
         self.generalSol = generalSol
         self.func = func
-        genList.append([id, title, self])
+
+        (filename, line_number, function_name, text) = traceback.extract_stack()[-2]
+        funcname = filename[filename.rfind('/'):].strip()
+        funcname = funcname[1:-3]
+        # print(funcname)
+        genList.append([id, title, self, funcname])
 
     def __str__(self):
         return str(
             self.id
         ) + " " + self.title + " " + self.generalProb + " " + self.generalSol
 
-    def __call__(self, **kwargs):
+    def __call__(self, *args, **kwargs):
-        return self.func(**kwargs)
+        return self.func(*args, **kwargs)
 
 
 def getGenList():

mathgenerator/funcs/__init__.py

@@ -2,91 +2,98 @@ import random
 import math
 import fractions
 
+from ..__init__ import *
+
 from .addition import *
-from .subtractionFunc import *
+from .subtraction import *
-from .multiplicationFunc import *
+from .multiplication import *
-from .divisionFunc import *
+from .division import *
-from .binaryComplement1sFunc import *
+from .binary_complement_1s import *
-from .moduloFunc import *
+from .modulo_division import *
-from .squareRootFunc import *
+from .square_root import *
-from .powerRuleDifferentiationFunc import *
+from .power_rule_differentiation import *
-from .squareFunc import *
+from .square import *
-from .lcmFunc import *
+from .lcm import *
-from .gcdFunc import *
+from .gcd import *
-from .basicAlgebraFunc import *
+from .basic_algebra import *
-from .logFunc import *
+from .log import *
-from .divisionToIntFunc import *
+from .int_division import *
-from .DecimalToBinaryFunc import *
+from .decimal_to_binary import *
-from .BinaryToDecimalFunc import *
+from .binary_to_decimal import *
-from .divideFractionsFunc import *
+from .divide_fractions import *
-from .multiplyIntToMatrix22 import *
+from .multiply_int_to_22_matrix import *
-from .areaOfTriangleFunc import *
+from .area_of_triangle import *
-from .isTriangleValidFunc import *
+from .valid_triangle import *
-from .MidPointOfTwoPointFunc import *
+from .midpoint_of_two_points import *
-from .factoringFunc import *
+from .factoring import *
-from .thirdAngleOfTriangleFunc import *
+from .third_angle_of_triangle import *
-from .systemOfEquationsFunc import *
+from .system_of_equations import *
-from .distanceTwoPointsFunc import *
+from .distance_two_points import *
-from .pythagoreanTheoremFunc import *
+from .pythagorean_theorem import *
-from .linearEquationsFunc import *
+from .linear_equations import *
-from .primeFactorsFunc import *
+from .prime_factors import *
-from .multiplyFractionsFunc import *
+from .fraction_multiplication import *
-from .regularPolygonAngleFunc import *
+from .angle_regular_polygon import *
-from .combinationsFunc import *
+from .combinations import *
-from .factorialFunc import *
+from .factorial import *
-from .surfaceAreaCube import *
+from .surface_area_cube import *
-from .surfaceAreaCuboid import *
+from .surface_area_cuboid import *
-from .surfaceAreaCylinder import *
+from .surface_area_cylinder import *
-from .volumeCube import *
+from .volume_cube import *
-from .volumeCuboid import *
+from .volume_cuboid import *
-from .volumeCylinder import *
+from .volume_cylinder import *
-from .surfaceAreaCone import *
+from .surface_area_cone import *
-from .volumeCone import *
+from .volume_cone import *
-from .commonFactorsFunc import *
+from .common_factors import *
-from .intersectionOfTwoLinesFunc import *
+from .intersection_of_two_lines import *
-from .permutationFunc import *
+from .permutation import *
-from .vectorCrossFunc import *
+from .vector_cross import *
-from .compareFractionsFunc import *
+from .compare_fractions import *
-from .simpleInterestFunc import *
+from .simple_interest import *
-from .matrixMultiplicationFunc import *
+from .matrix_multiplication import *
-from .cubeRootFunc import *
+from .cube_root import *
-from .powerRuleIntegrationFunc import *
+from .power_rule_integration import *
-from .fourthAngleOfQuadriFunc import *
+from .fourth_angle_of_quadrilateral import *
-from .quadraticEquation import *
+from .quadratic_equation import *
-from .hcfFunc import *
+from .hcf import *
-from .DiceSumProbFunc import *
+from .dice_sum_probability import *
-from .exponentiationFunc import *
+from .exponentiation import *
-from .confidenceIntervalFunc import *
+from .confidence_interval import *
-from .surdsComparisonFunc import *
+from .surds_comparison import *
-from .fibonacciSeriesFunc import *
+from .fibonacci_series import *
-from .basicTrigonometryFunc import *
+from .basic_trigonometry import *
-from .sumOfAnglesOfPolygonFunc import *
+from .sum_of_polygon_angles import *
-from .dataSummaryFunc import *
+from .data_summary import *
-from .surfaceAreaSphere import *
+from .surface_area_sphere import *
-from .volumeSphereFunc import *
+from .volume_sphere import *
-from .nthFibonacciNumberFunc import *
+from .nth_fibonacci_number import *
-from .profitLossPercentFunc import *
+from .profit_loss_percent import *
-from .binaryToHexFunc import *
+from .binary_to_hex import *
-from .multiplyComplexNumbersFunc import *
+from .multiply_complex_numbers import *
-from .geomProgrFunc import *
+from .geometric_progression import *
-from .geometricMeanFunc import *
+from .geometric_mean import *
-from .harmonicMeanFunc import *
+from .harmonic_mean import *
-from .euclidianNormFunc import *
+from .euclidian_norm import *
-from .angleBtwVectorsFunc import *
+from .angle_btw_vectors import *
-from .absoluteDifferenceFunc import *
+from .absolute_difference import *
-from .vectorDotFunc import *
+from .vector_dot import *
-from .binary2sComplement import *
+from .binary_2s_complement import *
-from .matrixInversion import *
+from .invert_matrix import *
-from .sectorAreaFunc import *
+from .sector_area import *
-from .meanMedianFunc import *
+from .mean_median import *
-from .determinantToMatrix22 import *
+from .int_matrix_22_determinant import *
-from .compoundInterestFunc import *
+from .compound_interest import *
-from .deciToHexaFunc import *
+from .decimal_to_hexadeci import *
-from .percentageFunc import *
+from .percentage import *
-from .celsiustofahrenheit import *
+from .celsius_to_fahrenheit import *
-from .arithmeticProgressionTermFunc import *
+from .arithmetic_progression_term import *
-from .arithmeticProgressionSumFunc import *
+from .arithmetic_progression_sum import *
-from .decimalToOctalFunc import *
+from .decimal_to_octal import *
-from .decimalToRomanNumeralsFunc import *
+from .decimal_to_roman_numerals import *
-from .degreeToRadFunc import *
+from .degree_to_rad import *
-from .radianToDegFunc import *
+from .radian_to_deg import *
+from .differentiation import *
+from .definite_integral import *
+from .is_prime import *
+from .bcd_to_decimal import *
+from .complex_to_polar import *

mathgenerator/funcs/absolute_difference.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def absoluteDifferenceFunc(maxA=100, maxB=100):
@@ -13,7 +12,7 @@ def absoluteDifferenceFunc(maxA=100, maxB=100):
     return problem, solution
 
 
-absoluteDifference = Generator(
+absolute_difference = Generator(
     "Absolute difference between two numbers", 71,
     "Absolute difference betweeen two numbers a and b =", "|a-b|",
     absoluteDifferenceFunc)

mathgenerator/funcs/addition.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def additionFunc(maxSum=99, maxAddend=50):

mathgenerator/funcs/angle_btw_vectors.py

@@ -1,5 +1,5 @@
 from .__init__ import *
-from ..__init__ import Generator
+import math
 
 
 def angleBtwVectorsFunc(maxEltAmt=20):
@@ -15,14 +15,14 @@ def angleBtwVectorsFunc(maxEltAmt=20):
     solution = ''
     try:
         solution = str(math.acos(s / mags))
-    except MathDomainError:
+    except ValueError:
         print('angleBtwVectorsFunc has some issues with math module, line 16')
         solution = 'NaN'
     # would return the answer in radians
     return problem, solution
 
 
-angleBtwVectors = Generator(
+angle_btw_vectors = Generator(
     "Angle between 2 vectors", 70,
     "Angle Between 2 vectors V1=[v11, v12, ..., v1n] and V2=[v21, v22, ....., v2n]",
     "V1.V2 / (euclidNorm(V1)*euclidNorm(V2))", angleBtwVectorsFunc)

mathgenerator/funcs/angle_regular_polygon.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def regularPolygonAngleFunc(minVal=3, maxVal=20):
@@ -11,7 +10,7 @@ def regularPolygonAngleFunc(minVal=3, maxVal=20):
     return problem, solution
 
 
-angleRegularPolygon = Generator(
+angle_regular_polygon = Generator(
     "Angle of a Regular Polygon", 29,
     "Find the angle of a regular polygon with 6 sides", "120",
     regularPolygonAngleFunc)

mathgenerator/funcs/area_of_triangle.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def areaOfTriangleFunc(maxA=20, maxB=20, maxC=20):
@@ -16,6 +15,6 @@ def areaOfTriangleFunc(maxA=20, maxB=20, maxC=20):
     return problem, solution
 
 
-areaOfTriangle = Generator("Area of Triangle", 18,
+area_of_triangle = Generator("Area of Triangle", 18,
                              "Area of Triangle with side lengths a, b, c = ",
                              "area", areaOfTriangleFunc)

mathgenerator/funcs/arithmetic_progression_sum.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def arithmeticProgressionSumFunc(maxd=100, maxa=100, maxn=100):
@@ -14,6 +13,6 @@ def arithmeticProgressionSumFunc(maxd=100, maxa=100, maxn=100):
     return problem, solution
 
 
-arithmeticProgressionSum = Generator("AP Sum Calculation", 83,
+arithmetic_progression_sum = Generator("AP Sum Calculation", 83,
                                        "Find the sum of first n terms of the AP series: a1, a2, a3 ...",
                                        "Sum", arithmeticProgressionSumFunc)

mathgenerator/funcs/arithmetic_progression_term.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def arithmeticProgressionTermFunc(maxd=100, maxa=100, maxn=100):
@@ -14,6 +13,6 @@ def arithmeticProgressionTermFunc(maxd=100, maxa=100, maxn=100):
     return problem, solution
 
 
-arithmeticProgressionTerm = Generator("AP Term Calculation", 82,
+arithmetic_progression_term = Generator("AP Term Calculation", 82,
                                         "Find the term number n of the AP series: a1, a2, a3 ...",
                                         "a-n", arithmeticProgressionTermFunc)

mathgenerator/funcs/basic_algebra.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def basicAlgebraFunc(maxVariable=10):
@@ -26,5 +25,5 @@ def basicAlgebraFunc(maxVariable=10):
     return problem, solution
 
 
-basicAlgebra = Generator("Basic Algebra", 11, "ax + b = c", "d",
+basic_algebra = Generator("Basic Algebra", 11, "ax + b = c", "d",
                           basicAlgebraFunc)

mathgenerator/funcs/basic_trigonometry.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 # Handles degrees in quadrant one
@@ -26,5 +25,5 @@ def basicTrigonometryFunc(angles=[0, 30, 45, 60, 90],
     return problem, solution
 
 
-basicTrigonometry = Generator("Trigonometric Values", 57, "What is sin(X)?",
+basic_trigonometry = Generator("Trigonometric Values", 57, "What is sin(X)?",
                                "ans", basicTrigonometryFunc)

mathgenerator/funcs/bcd_to_decimal.py

@@ -0,0 +1,24 @@
+from .__init__ import *
+
+
+def BCDtoDecimalFunc(maxNumber=10000):
+    n = random.randint(1000, maxNumber)
+    binstring = ''
+    while True:
+        q, r = divmod(n, 10)
+        nibble = bin(r).replace('0b', "")
+        while len(nibble) < 4:
+            nibble = '0' + nibble
+        binstring = nibble + binstring
+        if q == 0:
+            break
+        else:
+            n = q
+
+    problem = "Integer of Binary Coded Decimal " + str(n) + " is = "
+    solution = int(binstring, 2)
+    return problem, solution
+
+
+bcd_to_decimal = Generator("Binary Coded Decimal to Integer", 91,
+                           "Integer of Binary Coded Decimal b is ", "n", BCDtoDecimalFunc)

mathgenerator/funcs/binary_2s_complement.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def binary2sComplementFunc(maxDigits=10):
@@ -29,6 +28,6 @@ def binary2sComplementFunc(maxDigits=10):
     return problem, solution
 
 
-binary2sComplement = Generator("Binary 2's Complement", 73,
+binary_2s_complement = Generator("Binary 2's Complement", 73,
                                  "2's complement of 11010110 =", "101010",
                                  binary2sComplementFunc)

mathgenerator/funcs/binary_complement_1s.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def binaryComplement1sFunc(maxDigits=10):
@@ -16,5 +15,5 @@ def binaryComplement1sFunc(maxDigits=10):
     return problem, solution
 
 
-binaryComplement1s = Generator("Binary Complement 1s", 4, "1010=", "0101",
+binary_complement_1s = Generator("Binary Complement 1s", 4, "1010=", "0101",
                                  binaryComplement1sFunc)

mathgenerator/funcs/binary_to_decimal.py

@@ -1,8 +1,7 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
-def BinaryToDecimalFunc(max_dig=10):
+def binaryToDecimalFunc(max_dig=10):
     problem = ''
 
     for i in range(random.randint(1, max_dig)):
@@ -13,5 +12,5 @@ def BinaryToDecimalFunc(max_dig=10):
     return problem, solution
 
 
-binaryToDecimal = Generator("Binary to Decimal", 15, "Decimal of a=", "b",
+binary_to_decimal = Generator("Binary to Decimal", 15, "Decimal of a=", "b",
-                            BinaryToDecimalFunc)
+                              binaryToDecimalFunc)

mathgenerator/funcs/binary_to_hex.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def binaryToHexFunc(max_dig=10):
@@ -12,5 +11,5 @@ def binaryToHexFunc(max_dig=10):
     return problem, solution
 
 
-binaryToHex = Generator("Binary to Hexidecimal", 64, "Hexidecimal of a=", "b",
+binary_to_hex = Generator("Binary to Hexidecimal", 64, "Hexidecimal of a=", "b",
                           binaryToHexFunc)

mathgenerator/funcs/celsius_to_fahrenheit.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def celsiustofahrenheitFunc(maxTemp=100):
@@ -10,5 +9,5 @@ def celsiustofahrenheitFunc(maxTemp=100):
     return problem, solution
 
 
-celsiustofahrenheit = Generator("Celsius To Fahrenheit", 81,
+celsius_to_fahrenheit = Generator("Celsius To Fahrenheit", 81,
                                   "(C +(9/5))+32=", "F", celsiustofahrenheitFunc)

mathgenerator/funcs/combinations.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def combinationsFunc(maxlength=20):

mathgenerator/funcs/common_factors.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def commonFactorsFunc(maxVal=100):
@@ -25,6 +24,6 @@ def commonFactorsFunc(maxVal=100):
     return problem, solution
 
 
-commonFactors = Generator("Common Factors", 40,
+common_factors = Generator("Common Factors", 40,
                            "Common Factors of {a} and {b} = ", "[c, d, ...]",
                            commonFactorsFunc)

mathgenerator/funcs/compare_fractions.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def compareFractionsFunc(maxVal=10):
@@ -27,7 +26,7 @@ def compareFractionsFunc(maxVal=10):
     return problem, solution
 
 
-compareFractions = Generator(
+compare_fractions = Generator(
     "Compare Fractions", 44,
     "Which symbol represents the comparison between a/b and c/d?", ">/</=",
     compareFractionsFunc)

mathgenerator/funcs/complex_to_polar.py

@@ -0,0 +1,18 @@
+from .__init__ import *
+
+
+def complexToPolarFunc(minRealImaginaryNum=-20, maxRealImaginaryNum=20):
+    num = complex(random.randint(minRealImaginaryNum, maxRealImaginaryNum),
+                  random.randint(minRealImaginaryNum, maxRealImaginaryNum))
+    a = num.real
+    b = num.imag
+    r = round(math.hypot(a, b), 2)
+    theta = round(math.atan2(b, a), 2)
+    plr = str(r) + "exp(i" + str(theta) + ")"
+    problem = f"rexp(itheta) = "
+    solution = plr
+    return problem, solution
+
+
+complex_to_polar = Generator("Complex To Polar Form", 92,
+                             "rexp(itheta) = ", "plr", complexToPolarFunc)

mathgenerator/funcs/compoundInterestFunc.py

@@ -1,25 +0,0 @@
-from .__init__ import *
-from ..__init__ import Generator
-
-
-def compoundInterestFunc(maxPrinciple=10000,
-                         maxRate=10,
-                         maxTime=10,
-                         maxPeriod=10):
-    p = random.randint(100, maxPrinciple)
-    r = random.randint(1, maxRate)
-    t = random.randint(1, maxTime)
-    n = random.randint(1, maxPeriod)
-    A = p * ((1 + (r / (100 * n))**(n * t)))
-    problem = "Compound Interest for a principle amount of " + str(
-        p) + " dollars, " + str(
-            r) + "% rate of interest and for a time period of " + str(
-                t) + " compounded monthly is = "
-    solution = round(A, 2)
-    return problem, solution
-
-
-compoundInterest = Generator(
-    "Compound Interest", 78,
-    "Compound interest for a principle amount of p dollars, r% rate of interest and for a time period of t years with n times compounded annually is = ",
-    "A dollars", compoundInterestFunc)

mathgenerator/funcs/compound_interest.py

@@ -0,0 +1,17 @@
+from .__init__ import *
+
+
+def compoundInterestFunc(maxPrinciple=10000, maxRate=10, maxTime=10):
+    p = random.randint(1000, maxPrinciple)
+    r = random.randint(1, maxRate)
+    n = random.randint(1, maxTime)
+    a = p * (1 + r / 100)**n
+    problem = "Compound interest for a principle amount of " + \
+        str(p) + " dollars, " + str(r) + \
+        "% rate of interest and for a time period of " + str(n) + " year is = "
+    solution = round(a, 2)
+    return problem, solution
+
+
+compound_interest = Generator(
+    "Compound Interest", 78, "Compound interest for a principle amount of a dollars, b% rate of interest and for a time period of c years is = ", "d dollars", compoundInterestFunc)

mathgenerator/funcs/confidence_interval.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def confidenceIntervalFunc():
@@ -32,6 +31,6 @@ def confidenceIntervalFunc():
     return problem, solution
 
 
-confidenceInterval = Generator("Confidence interval For sample S", 54,
+confidence_interval = Generator("Confidence interval For sample S", 54,
                                 "With X% confidence", "is (A,B)",
                                 confidenceIntervalFunc)

mathgenerator/funcs/cube_root.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def cubeRootFunc(minNo=1, maxNo=1000):
@@ -11,5 +10,5 @@ def cubeRootFunc(minNo=1, maxNo=1000):
     return problem, solution
 
 
-CubeRoot = Generator("Cube Root", 47, "Cuberoot of a upto 2 decimal places is",
+cube_root = Generator("Cube Root", 47, "Cuberoot of a upto 2 decimal places is",
                       "b", cubeRootFunc)

mathgenerator/funcs/data_summary.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def dataSummaryFunc(number_values=15, minval=5, maxval=50):
@@ -16,18 +15,15 @@ def dataSummaryFunc(number_values=15, minval=5, maxval=50):
     for i in range(number_values):
         var += (random_list[i] - mean)**2
 
-    # we're printing stuff here?
+    standardDeviation = var / number_values
-    print(random_list)
+    variance = (var / number_values) ** 0.5
-    print(mean)
-    print(var / number_values)
-    print((var / number_values)**0.5)
 
     problem = "Find the mean,standard deviation and variance for the data" + \
         str(random_list)
     solution = "The Mean is {} , Standard Deviation is {}, Variance is {}".format(
-        mean, var / number_values, (var / number_values)**0.5)
+        mean, standardDeviation, variance)
     return problem, solution
 
 
-dataSummary = Generator("Mean,Standard Deviation,Variance", 59, "a,b,c",
+data_summary = Generator("Mean,Standard Deviation,Variance", 59, "a,b,c",
                          "Mean:a+b+c/3,Std,Var", dataSummaryFunc)

mathgenerator/funcs/decimal_to_binary.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def DecimalToBinaryFunc(max_dec=99):
@@ -12,5 +11,5 @@ def DecimalToBinaryFunc(max_dec=99):
     return problem, solution
 
 
-decimalToBinary = Generator("Decimal to Binary", 14, "Binary of a=", "b",
+decimal_to_binary = Generator("Decimal to Binary", 14, "Binary of a=", "b",
                               DecimalToBinaryFunc)

mathgenerator/funcs/decimal_to_hexadeci.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def deciToHexaFunc(max_dec=1000):
@@ -11,5 +10,5 @@ def deciToHexaFunc(max_dec=1000):
     return problem, solution
 
 
-decimalToHexadeci = Generator("Decimal to Hexadecimal", 79, "Binary of a=",
+decimal_to_hexadeci = Generator("Decimal to Hexadecimal", 79, "Binary of a=",
                                 "b", deciToHexaFunc)

mathgenerator/funcs/decimal_to_octal.py

@@ -8,5 +8,5 @@ def decimalToOctalFunc(maxDecimal=4096):
     return problem, solution
 
 
-decimalToOctal = Generator("Converts decimal to octal", 84,
+decimal_to_octal = Generator("Converts decimal to octal", 84,
                              "What's the octal representation of 98?", "0o142", decimalToOctalFunc)

mathgenerator/funcs/decimal_to_roman_numerals.py

@@ -15,7 +15,7 @@ def decimalToRomanNumeralsFunc(maxDecimal=4000):
         if last_value <= 3:
             solution += (roman_dict[divisor] * last_value)
         elif last_value == 4:
-            solution += (roman_dict[divisor] * roman_dict[divisor * 5])
+            solution += (roman_dict[divisor] + roman_dict[divisor * 5])
         elif 5 <= last_value <= 8:
             solution += (roman_dict[divisor * 5] + (roman_dict[divisor] * (last_value - 5)))
         elif last_value == 9:
@@ -25,5 +25,5 @@ def decimalToRomanNumeralsFunc(maxDecimal=4000):
     return problem, solution
 
 
-decimalToRomanNumerals = Generator("Converts decimal to Roman Numerals",
+decimal_to_roman_numerals = Generator("Converts decimal to Roman Numerals",
                                       85, "Convert 20 into Roman Numerals", "XX", decimalToRomanNumeralsFunc)

mathgenerator/funcs/definite_integral.py

@@ -0,0 +1,27 @@
+from .__init__ import *
+import scipy
+from scipy.integrate import quad
+
+
+def definiteIntegralFunc(max_coeff=100):
+
+    def integrand(x, a, b, c):
+        return a * x ** 2 + b * x + c
+
+    a = random.randint(0, max_coeff)
+    b = random.randint(0, max_coeff)
+    c = random.randint(0, max_coeff)
+
+    result = quad(integrand, 0, 1, args=(a, b, c))[0]
+    S = round(result, 4)
+
+    problem = "The definite integral within limits 0 to 1 of the equation " + \
+        str(a) + "x^2 + " + str(b) + "x + " + str(c) + " is = "
+
+    solution = str(S)
+
+    return problem, solution
+
+
+definite_integral = Generator("Definite Integral of Quadratic Equation", 89,
+                              "The definite integral within limits 0 to 1 of quadratic equation ax^2+bx+c is = ", "S", definiteIntegralFunc)

mathgenerator/funcs/degree_to_rad.py

@@ -13,4 +13,5 @@ def degreeToRadFunc(max_deg=360):
     return problem, solution
 
 
-degreeToRad = Generator("Degrees to Radians", 86, "Angle a in radians is = ", "b", degreeToRadFunc)
+degree_to_rad = Generator("Degrees to Radians", 86,
+                          "Angle a in radians is = ", "b", degreeToRadFunc)

mathgenerator/funcs/dice_sum_probability.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def DiceSumProbFunc(maxDice=3):
@@ -27,7 +26,7 @@ def DiceSumProbFunc(maxDice=3):
     return problem, solution
 
 
-diceSumProbability = Generator(
+dice_sum_probability = Generator(
     "Probability of a certain sum appearing on faces of dice", 52,
     "If n dices are rolled then probabilty of getting sum of x is =", "z",
     DiceSumProbFunc)

mathgenerator/funcs/differentiation.py

@@ -0,0 +1,53 @@
+from .__init__ import *
+
+
+def genDifferentiationProblem(diff_lvl):
+    problem = ''
+
+    types = {
+        'Logrithmic': ['ln'],
+        'Trigonometric': ['sin', 'cos', 'tan', 'cot', 'sec'],
+        'Exponentional': ['exp']
+    }
+
+    if diff_lvl == 1:
+        coeff = random.randrange(2, 10)
+        power = random.randint(2, 4)
+        flag = random.random()
+        if flag > 0.5:
+            power *= -1
+            problem += str(coeff) + '*x^' + '(' + str(power) + ')'
+        else:
+            problem += str(coeff) + '*x^' + str(power)
+    if diff_lvl == 2:
+        func_type = random.choices(list(types.keys()), weights=(1, 4, 1))[0]
+        func = random.choice(types[func_type])
+        problem += func + '(x)' + '+' + genDifferentiationProblem(1)
+    if diff_lvl == 3:
+        func_type = random.choices(list(types.keys()), weights=(1, 4, 1))[0]
+        func = random.choice(types[func_type])
+        problem += func + '(' + genDifferentiationProblem(1) + ')'
+    if diff_lvl == 4:
+        operator = random.choice(('/', '*'))
+        problem = '(' + genDifferentiationProblem(2) + ')' + \
+            operator + '(' + genDifferentiationProblem(3) + ')'
+
+    return problem
+
+
+def differentiationFunc(diff_lvl=2):
+    if diff_lvl < 1 or diff_lvl > 4:
+        print("diff_lvl not supported")
+        return None
+    problem = genDifferentiationProblem(diff_lvl)
+
+    x = sympy.symbols('x')
+    solution = str(sympy.diff(problem.replace('^', '**'), x))
+    solution = solution.replace('**', '^')
+    problem = f"differentiate w.r.t x : d({problem})/dx"
+
+    return problem, solution
+
+
+differentiation = Generator(
+    "Differentiation", 88, "differentiate w.r.t x : d(f(x))/dx", "g(x)", differentiationFunc)

mathgenerator/funcs/distance_two_points.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def distanceTwoPointsFunc(maxValXY=20, minValXY=-20):
@@ -15,6 +14,6 @@ def distanceTwoPointsFunc(maxValXY=20, minValXY=-20):
     return problem, solution
 
 
-distance2Point = Generator("Distance between 2 points", 24,
+distance_two_points = Generator("Distance between 2 points", 24,
                                 "Find the distance between (x1,y1) and (x2,y2)",
                                 "sqrt(distanceSquared)", distanceTwoPointsFunc)

mathgenerator/funcs/divide_fractions.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def divideFractionsFunc(maxVal=10):
@@ -33,5 +32,5 @@ def divideFractionsFunc(maxVal=10):
     return problem, solution
 
 
-fractionDivision = Generator("Fraction Division", 16, "(a/b)/(c/d)=", "x/y",
+divide_fractions = Generator("Fraction Division", 16, "(a/b)/(c/d)=", "x/y",
                              divideFractionsFunc)

mathgenerator/funcs/division.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def divisionFunc(maxRes=99, maxDivid=99):

mathgenerator/funcs/euclidian_norm.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def euclidianNormFunc(maxEltAmt=20):
@@ -9,6 +8,6 @@ def euclidianNormFunc(maxEltAmt=20):
     return problem, solution
 
 
-eucldianNorm = Generator("Euclidian norm or L2 norm of a vector", 69,
+eucldian_norm = Generator("Euclidian norm or L2 norm of a vector", 69,
                           "Euclidian Norm of a vector V:[v1, v2, ......., vn]",
                           "sqrt(v1^2 + v2^2 ........ +vn^2)", euclidianNormFunc)

mathgenerator/funcs/exponentiation.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def exponentiationFunc(maxBase=20, maxExpo=10):

mathgenerator/funcs/factorial.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def factorialFunc(maxInput=6):

mathgenerator/funcs/factoring.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def factoringFunc(range_x1=10, range_x2=10):

mathgenerator/funcs/fibonacci_series.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def fibonacciSeriesFunc(minNo=1):
@@ -22,6 +21,6 @@ def fibonacciSeriesFunc(minNo=1):
     return problem, solution
 
 
-fibonacciSeries = Generator(
+fibonacci_series = Generator(
     "Fibonacci Series", 56, "fibonacci series of first a numbers",
     "prints the fibonacci series starting from 0 to a", fibonacciSeriesFunc)

mathgenerator/funcs/fourth_angle_of_quadrilateral.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def fourthAngleOfQuadriFunc(maxAngle=180):
@@ -15,7 +14,7 @@ def fourthAngleOfQuadriFunc(maxAngle=180):
     return problem, solution
 
 
-fourthAngleOfQuadrilateral = Generator(
+fourth_angle_of_quadrilateral = Generator(
     "Fourth Angle of Quadrilateral", 49,
     "Fourth angle of Quadrilateral with angles a,b,c =", "angle4",
     fourthAngleOfQuadriFunc)

mathgenerator/funcs/fraction_multiplication.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def multiplyFractionsFunc(maxVal=10):
@@ -33,6 +32,6 @@ def multiplyFractionsFunc(maxVal=10):
     return problem, solution
 
 
-fractionMultiplication = Generator("Fraction Multiplication", 28,
+fraction_multiplication = Generator("Fraction Multiplication", 28,
                                     "(a/b)*(c/d)=", "x/y",
                                     multiplyFractionsFunc)

mathgenerator/funcs/gcd.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def gcdFunc(maxVal=20):

mathgenerator/funcs/geometric_mean.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def geometricMeanFunc(maxValue=100, maxNum=4):
@@ -28,6 +27,6 @@ def geometricMeanFunc(maxValue=100, maxNum=4):
     return problem, solution
 
 
-geometricMean = Generator("Geometric Mean of N Numbers", 67,
+geometric_mean = Generator("Geometric Mean of N Numbers", 67,
                            "Geometric mean of n numbers A1 , A2 , ... , An = ",
                            "(A1*A2*...An)^(1/n) = ans", geometricMeanFunc)

mathgenerator/funcs/geometric_progression.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def geomProgrFunc(number_values=6,
@@ -24,7 +23,7 @@ def geomProgrFunc(number_values=6,
     return problem, solution
 
 
-geometricprogression = Generator(
+geometric_progression = Generator(
     "Geometric Progression", 66,
     "Initial value,Common Ratio,nth Term,Sum till nth term =",
     "a,r,ar^n-1,sum(ar^n-1", geomProgrFunc)

mathgenerator/funcs/harmonic_mean.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def harmonicMeanFunc(maxValue=100, maxNum=4):
@@ -29,7 +28,7 @@ def harmonicMeanFunc(maxValue=100, maxNum=4):
     return problem, solution
 
 
-harmonicMean = Generator("Harmonic Mean of N Numbers", 68,
+harmonic_mean = Generator("Harmonic Mean of N Numbers", 68,
                           "Harmonic mean of n numbers A1 , A2 , ... , An = ",
                           " n/((1/A1) + (1/A2) + ... + (1/An)) = ans",
                           harmonicMeanFunc)

mathgenerator/funcs/hcf.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def hcfFunc(maxVal=20):

mathgenerator/funcs/int_division.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def divisionToIntFunc(maxA=25, maxB=25):
@@ -14,4 +13,4 @@ def divisionToIntFunc(maxA=25, maxB=25):
     return problem, solution
 
 
-intDivision = Generator("Easy Division", 13, "a/b=", "c", divisionToIntFunc)
+int_division = Generator("Easy Division", 13, "a/b=", "c", divisionToIntFunc)

mathgenerator/funcs/int_matrix_22_determinant.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def determinantToMatrix22(maxMatrixVal=100):
@@ -14,6 +13,6 @@ def determinantToMatrix22(maxMatrixVal=100):
     return problem, solution
 
 
-intMatrix22determinant = Generator("Determinant to 2x2 Matrix", 77,
+int_matrix_22_determinant = Generator("Determinant to 2x2 Matrix", 77,
                                       "Det([[a,b],[c,d]]) =", " a * d - b * c",
                                       determinantToMatrix22)

mathgenerator/funcs/intersection_of_two_lines.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def intersectionOfTwoLinesFunc(minM=-10,
@@ -67,7 +66,7 @@ def intersectionOfTwoLinesFunc(minM=-10,
     return problem, solution
 
 
-intersectionOfTwoLines = Generator(
+intersection_of_two_lines = Generator(
     "Intersection of Two Lines", 41,
     "Find the point of intersection of the two lines: y = m1*x + b1 and y = m2*x + b2",
     "(x, y)", intersectionOfTwoLinesFunc)

mathgenerator/funcs/invert_matrix.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 import sympy
 
 
@@ -79,5 +78,5 @@ def matrixInversion(SquareMatrixDimension=3,
     return problem, solution
 
 
-invertmatrix = Generator("Inverse of a Matrix", 74, "Inverse of a matrix A is",
+invert_matrix = Generator("Inverse of a Matrix", 74, "Inverse of a matrix A is",
                           "A^(-1)", matrixInversion)

mathgenerator/funcs/is_prime.py

@@ -0,0 +1,22 @@
+from .__init__ import *
+
+
+def isprime(max_a=100):
+    a = random.randint(2, max_a)
+    problem = a
+    if a == 2:
+        solution = True
+        return (problem, solution)
+    if a % 2 == 0:
+        solution = False
+        return (problem, solution)
+    for i in range(3, a // 2 + 1, 2):
+        if a % i == 0:
+            solution = False
+            return (problem, solution)
+    solution = True
+    return (problem, solution)
+
+
+is_prime = Generator('isprime', 90, 'a any positive integer',
+                     'True/False', isprime)

mathgenerator/funcs/lcm.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def lcmFunc(maxVal=20):

mathgenerator/funcs/linear_equations.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def linearEquationsFunc(n=2, varRange=20, coeffRange=20):
@@ -26,9 +25,10 @@ def linearEquationsFunc(n=2, varRange=20, coeffRange=20):
         prob = " + ".join(prob) + " = " + str(res)
         problem.append(prob)
 
-    problem = "\n".join(problem)
+    # problem = "\n".join(problem)
+    problem = ", ".join(problem)
     return problem, solution
 
 
-linearEquations = Generator("Linear Equations", 26, "2x+5y=20 & 3x+6y=12",
+linear_equations = Generator("Linear Equations", 26, "2x+5y=20 & 3x+6y=12",
                              "x=-20 & y=12", linearEquationsFunc)

mathgenerator/funcs/log.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def logFunc(maxBase=3, maxVal=8):

mathgenerator/funcs/matrix_multiplication.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def matrixMultiplicationFunc(maxVal=100, max_dim=10):
@@ -54,6 +53,6 @@ def matrixMultiplicationFuncHelper(inp):
     return string
 
 
-matrixMultiplication = Generator("Multiplication of two matrices", 46,
+matrix_multiplication = Generator("Multiplication of two matrices", 46,
                                   "Multiply two matrices A and B", "C",
                                   matrixMultiplicationFunc)

mathgenerator/funcs/mean_median.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def meanMedianFunc(maxlen=10):
@@ -15,6 +14,6 @@ def meanMedianFunc(maxlen=10):
     return problem, solution
 
 
-meanMedian = Generator("Mean and Median", 76,
+mean_median = Generator("Mean and Median", 76,
                         "Mean and median of given set of numbers",
                         "Mean, Median", meanMedianFunc)

mathgenerator/funcs/midpoint_of_two_points.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def MidPointOfTwoPointFunc(maxValue=20):
@@ -13,6 +12,6 @@ def MidPointOfTwoPointFunc(maxValue=20):
     return problem, solution
 
 
-midPointOfTwoPoint = Generator("Midpoint of the two point", 20,
+midPoint_of_two_points = Generator("Midpoint of the two point", 20,
                                    "((X1,Y1),(X2,Y2))=", "((X1+X2)/2,(Y1+Y2)/2)",
                                    MidPointOfTwoPointFunc)

mathgenerator/funcs/modulo_division.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def moduloFunc(maxRes=99, maxModulo=99):
@@ -12,4 +11,4 @@ def moduloFunc(maxRes=99, maxModulo=99):
     return problem, solution
 
 
-moduloDivision = Generator("Modulo Division", 5, "a%b=", "c", moduloFunc)
+modulo_division = Generator("Modulo Division", 5, "a%b=", "c", moduloFunc)

mathgenerator/funcs/multiplication.py

@@ -1,9 +1,11 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def multiplicationFunc(maxRes=99, maxMulti=99):
     a = random.randint(0, maxMulti)
+    if a == 0:
+        b = random.randint(0, maxRes)
+    else:
         b = random.randint(0, min(int(maxMulti / a), maxRes))
     c = a * b
 

mathgenerator/funcs/multiply_complex_numbers.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def multiplyComplexNumbersFunc(minRealImaginaryNum=-20,
@@ -13,6 +12,6 @@ def multiplyComplexNumbersFunc(minRealImaginaryNum=-20,
     return problem, solution
 
 
-complexNumMultiply = Generator("Multiplication of 2 complex numbers", 65,
+multiply_complex_numbers = Generator("Multiplication of 2 complex numbers", 65,
                                      "(x + j) (y + j) = ", "xy + xj + yj -1",
                                      multiplyComplexNumbersFunc)

mathgenerator/funcs/multiply_int_to_22_matrix.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def multiplyIntToMatrix22(maxMatrixVal=10, maxRes=100):
@@ -14,7 +13,7 @@ def multiplyIntToMatrix22(maxMatrixVal=10, maxRes=100):
     return problem, solution
 
 
-intMatrix22Multiplication = Generator("Integer Multiplication with 2x2 Matrix",
+multiply_int_to_22_matrix = Generator("Integer Multiplication with 2x2 Matrix",
                                       17, "k * [[a,b],[c,d]]=",
                                       "[[k*a,k*b],[k*c,k*d]]",
                                       multiplyIntToMatrix22)

mathgenerator/funcs/nth_fibonacci_number.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def nthFibonacciNumberFunc(maxN=100):
@@ -11,6 +10,6 @@ def nthFibonacciNumberFunc(maxN=100):
     return problem, solution
 
 
-nthFibonacciNumberGen = Generator("nth Fibonacci number", 62,
+nth_fibonacci_number = Generator("nth Fibonacci number", 62,
                                  "What is the nth Fibonacci number", "Fn",
                                  nthFibonacciNumberFunc)

mathgenerator/funcs/percentage.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def percentageFunc(maxValue=99, maxpercentage=99):

mathgenerator/funcs/permutation.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def permutationFunc(maxlength=20):
@@ -12,7 +11,7 @@ def permutationFunc(maxlength=20):
     return problem, solution
 
 
-permutations = Generator(
+permutation = Generator(
     "Permutations", 42,
     "Total permutations of 4 objects at a time from 10 objects is", "5040",
     permutationFunc)

mathgenerator/funcs/power_rule_differentiation.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def powerRuleDifferentiationFunc(maxCoef=10, maxExp=10, maxTerms=5):
@@ -19,6 +18,6 @@ def powerRuleDifferentiationFunc(maxCoef=10, maxExp=10, maxTerms=5):
     return problem, solution
 
 
-powerRuleDifferentiation = Generator("Power Rule Differentiation", 7, "nx^m=",
+power_rule_differentiation = Generator("Power Rule Differentiation", 7, "nx^m=",
                                        "(n*m)x^(m-1)",
                                        powerRuleDifferentiationFunc)

mathgenerator/funcs/power_rule_integration.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def powerRuleIntegrationFunc(maxCoef=10, maxExp=10, maxTerms=5):
@@ -22,5 +21,5 @@ def powerRuleIntegrationFunc(maxCoef=10, maxExp=10, maxTerms=5):
     return problem, solution
 
 
-powerRuleIntegration = Generator("Power Rule Integration", 48, "nx^m=",
+power_rule_integration = Generator("Power Rule Integration", 48, "nx^m=",
                                    "(n/m)x^(m+1)", powerRuleIntegrationFunc)

mathgenerator/funcs/prime_factors.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def primeFactorsFunc(minVal=1, maxVal=200):
@@ -23,5 +22,5 @@ def primeFactorsFunc(minVal=1, maxVal=200):
     return problem, solution
 
 
-primeFactors = Generator("Prime Factorisation", 27, "Prime Factors of a =",
+prime_factors = Generator("Prime Factorisation", 27, "Prime Factors of a =",
                           "[b, c, d, ...]", primeFactorsFunc)

mathgenerator/funcs/profit_loss_percent.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def profitLossPercentFunc(maxCP=1000, maxSP=1000):
@@ -17,7 +16,7 @@ def profitLossPercentFunc(maxCP=1000, maxSP=1000):
     return problem, solution
 
 
-profitLossPercent = Generator(
+profit_loss_percent = Generator(
     "Profit or Loss Percent", 63,
     "Profit/ Loss percent when CP = cp and SP = sp is: ", "percent",
     profitLossPercentFunc)

mathgenerator/funcs/pythagorean_theorem.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def pythagoreanTheoremFunc(maxLength=20):
@@ -12,7 +11,7 @@ def pythagoreanTheoremFunc(maxLength=20):
     return problem, solution
 
 
-pythagoreanTheorem = Generator(
+pythagorean_theorem = Generator(
     "Pythagorean Theorem", 25,
     "The hypotenuse of a right triangle given the other two lengths a and b = ",
     "hypotenuse", pythagoreanTheoremFunc)

mathgenerator/funcs/quadratic_equation.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def quadraticEquation(maxVal=100):
@@ -16,7 +15,7 @@ def quadraticEquation(maxVal=100):
     return problem, solution
 
 
-quadraticEquationSolve = Generator(
+quadratic_equation = Generator(
     "Quadratic Equation", 50,
     "Find the zeros {x1,x2} of the quadratic equation ax^2+bx+c=0", "x1,x2",
     quadraticEquation)

mathgenerator/funcs/radian_to_deg.py

@@ -2,7 +2,8 @@ from .__init__ import *
 from numpy import pi
 
 
-def radianToDegFunc(max_rad=pi):
+def radianToDegFunc(max_rad=3):
+    # max_rad is supposed to be pi but random can't handle non-integer
     a = random.randint(0, max_rad)
     b = (180 * a) / pi
     b = round(b, 2)
@@ -13,4 +14,5 @@ def radianToDegFunc(max_rad=pi):
     return problem, solution
 
 
-radianToDeg = Generator("Radians to Degrees", 87, "Angle a in degrees is = ", "b", radianToDegFunc)
+radian_to_deg = Generator("Radians to Degrees", 87,
+                          "Angle a in degrees is = ", "b", radianToDegFunc)

mathgenerator/funcs/sector_area.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def sectorAreaFunc(maxRadius=49, maxAngle=359):
@@ -12,6 +11,6 @@ def sectorAreaFunc(maxRadius=49, maxAngle=359):
     return problem, solution
 
 
-sectorArea = Generator("Area of a Sector", 75,
+sector_area = Generator("Area of a Sector", 75,
                         "Area of a sector with radius, r and angle, a ", "Area",
                         sectorAreaFunc)

mathgenerator/funcs/simple_interest.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def simpleInterestFunc(maxPrinciple=10000, maxRate=10, maxTime=10):
@@ -16,7 +15,7 @@ def simpleInterestFunc(maxPrinciple=10000, maxRate=10, maxTime=10):
     return problem, solution
 
 
-simpleInterest = Generator(
+simple_interest = Generator(
     "Simple Interest", 45,
     "Simple interest for a principle amount of a dollars, b% rate of interest and for a time period of c years is = ",
     "d dollars", simpleInterestFunc)

mathgenerator/funcs/square.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def squareFunc(maxSquareNum=20):

mathgenerator/funcs/square_root.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def squareRootFunc(minNo=1, maxNo=12):
@@ -11,4 +10,4 @@ def squareRootFunc(minNo=1, maxNo=12):
     return problem, solution
 
 
-squareRoot = Generator("Square Root", 6, "sqrt(a)=", "b", squareRootFunc)
+square_root = Generator("Square Root", 6, "sqrt(a)=", "b", squareRootFunc)

mathgenerator/funcs/subtraction.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def subtractionFunc(maxMinuend=99, maxDiff=99):

mathgenerator/funcs/sum_of_polygon_angles.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def sumOfAnglesOfPolygonFunc(maxSides=12):
@@ -11,6 +10,6 @@ def sumOfAnglesOfPolygonFunc(maxSides=12):
     return problem, solution
 
 
-sumOfAnglesOfPolygon = Generator("Sum of Angles of Polygon", 58,
+sum_of_polygon_angles = Generator("Sum of Angles of Polygon", 58,
                                   "Sum of angles of polygon with n sides = ",
                                   "sum", sumOfAnglesOfPolygonFunc)

mathgenerator/funcs/surds_comparison.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surdsComparisonFunc(maxValue=100, maxRoot=10):
@@ -18,6 +17,6 @@ def surdsComparisonFunc(maxValue=100, maxRoot=10):
     return problem, solution
 
 
-surdsComparison = Generator("Comparing surds", 55,
+surds_comparison = Generator("Comparing surds", 55,
                              "Fill in the blanks a^(1/b) _ c^(1/d)", "</>/=",
                              surdsComparisonFunc)

mathgenerator/funcs/surface_area_cone.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surfaceAreaCone(maxRadius=20, maxHeight=50, unit='m'):
@@ -14,7 +13,7 @@ def surfaceAreaCone(maxRadius=20, maxHeight=50, unit='m'):
     return problem, solution
 
 
-surfaceAreaConeGen = Generator(
+surface_area_cone = Generator(
     "Surface Area of cone", 38,
     "Surface area of cone with height = a units and radius = b units is",
     "c units^2", surfaceAreaCone)

mathgenerator/funcs/surface_area_cube.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surfaceAreaCube(maxSide=20, unit='m'):
@@ -10,6 +9,6 @@ def surfaceAreaCube(maxSide=20, unit='m'):
     return problem, solution
 
 
-surfaceAreaCubeGen = Generator("Surface Area of Cube", 32,
+surface_area_cube = Generator("Surface Area of Cube", 32,
                               "Surface area of cube with side a units is",
                               "b units^2", surfaceAreaCube)

mathgenerator/funcs/surface_area_cuboid.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surfaceAreaCuboid(maxSide=20, unit='m'):
@@ -13,7 +12,7 @@ def surfaceAreaCuboid(maxSide=20, unit='m'):
     return problem, solution
 
 
-surfaceAreaCuboidGen = Generator(
+surface_area_cuboid = Generator(
     "Surface Area of Cuboid", 33,
     "Surface area of cuboid with sides = a units, b units, c units is",
     "d units^2", surfaceAreaCuboid)

mathgenerator/funcs/surface_area_cylinder.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surfaceAreaCylinder(maxRadius=20, maxHeight=50, unit='m'):
@@ -12,7 +11,7 @@ def surfaceAreaCylinder(maxRadius=20, maxHeight=50, unit='m'):
     return problem, solution
 
 
-surfaceAreaCylinderGen = Generator(
+surface_area_cylinder = Generator(
     "Surface Area of Cylinder", 34,
     "Surface area of cylinder with height = a units and radius = b units is",
     "c units^2", surfaceAreaCylinder)

mathgenerator/funcs/surface_area_sphere.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def surfaceAreaSphere(maxSide=20, unit='m'):
@@ -11,7 +10,7 @@ def surfaceAreaSphere(maxSide=20, unit='m'):
     return problem, solution
 
 
-surfaceAreaSphereGen = Generator(
+surface_area_sphere = Generator(
     "Surface Area of Sphere", 60,
     "Surface area of sphere with radius = a units is", "d units^2",
     surfaceAreaSphere)

mathgenerator/funcs/system_of_equations.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def systemOfEquationsFunc(range_x=10, range_y=10, coeff_mult_range=10):
@@ -48,6 +47,6 @@ def systemOfEquationsFunc(range_x=10, range_y=10, coeff_mult_range=10):
     # Add random (non-zero) multiple of equations to each other
 
 
-systemOfEquations = Generator("Solve a System of Equations in R^2", 23,
+system_of_equations = Generator("Solve a System of Equations in R^2", 23,
                                 "2x + 5y = 13, -3x - 3y = -6", "x = -1, y = 3",
                                 systemOfEquationsFunc)

mathgenerator/funcs/third_angle_of_triangle.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def thirdAngleOfTriangleFunc(maxAngle=89):
@@ -12,6 +11,6 @@ def thirdAngleOfTriangleFunc(maxAngle=89):
     return problem, solution
 
 
-thirdAngleOfTriangle = Generator("Third Angle of Triangle", 22,
+third_angle_of_triangle = Generator("Third Angle of Triangle", 22,
                                     "Third Angle of the triangle = ", "angle3",
                                     thirdAngleOfTriangleFunc)

mathgenerator/funcs/valid_triangle.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def isTriangleValidFunc(maxSideLength=50):
@@ -21,6 +20,6 @@ def isTriangleValidFunc(maxSideLength=50):
     return problem, solution
 
 
-doesTriangleExist = Generator("Triangle exists check", 19,
+valid_triangle = Generator("Triangle exists check", 19,
                            "Does triangle with sides a, b and c exist?",
                            "Yes/No", isTriangleValidFunc)

mathgenerator/funcs/vector_cross.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def vectorCrossFunc(minVal=-20, maxVal=20):
@@ -15,5 +14,5 @@ def vectorCrossFunc(minVal=-20, maxVal=20):
     return problem, solution
 
 
-vectorCross = Generator("Cross Product of 2 Vectors", 43, "a X b = ", "c",
+vector_cross = Generator("Cross Product of 2 Vectors", 43, "a X b = ", "c",
                          vectorCrossFunc)

mathgenerator/funcs/vector_dot.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def vectorDotFunc(minVal=-20, maxVal=20):
@@ -12,5 +11,5 @@ def vectorDotFunc(minVal=-20, maxVal=20):
     return problem, solution
 
 
-vectorDot = Generator("Dot Product of 2 Vectors", 72, "a . b = ", "c",
+vector_dot = Generator("Dot Product of 2 Vectors", 72, "a . b = ", "c",
                        vectorDotFunc)

mathgenerator/funcs/volume_cone.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def volumeCone(maxRadius=20, maxHeight=50, unit='m'):
@@ -12,7 +11,7 @@ def volumeCone(maxRadius=20, maxHeight=50, unit='m'):
     return problem, solution
 
 
-volumeConeGen = Generator(
+volume_cone = Generator(
     "Volume of cone", 39,
     "Volume of cone with height = a units and radius = b units is",
     "c units^3", volumeCone)

mathgenerator/funcs/volume_cube.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def volumeCube(maxSide=20, unit='m'):
@@ -11,6 +10,6 @@ def volumeCube(maxSide=20, unit='m'):
     return problem, solution
 
 
-volumeCubeGen = Generator("Volum of Cube", 35,
+volume_cube = Generator("Volum of Cube", 35,
                         "Volume of cube with side a units is", "b units^3",
                         volumeCube)

mathgenerator/funcs/volume_cuboid.py

@@ -1,5 +1,4 @@
 from .__init__ import *
-from ..__init__ import Generator
 
 
 def volumeCuboid(maxSide=20, unit='m'):
@@ -13,7 +12,7 @@ def volumeCuboid(maxSide=20, unit='m'):
     return problem, solution
 
 
-volumeCuboidGen = Generator(
+volume_cuboid = Generator(
     "Volume of Cuboid", 36,
     "Volume of cuboid with sides = a units, b units, c units is", "d units^3",
     volumeCuboid)