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3 added 6 characters in body; added 25 characters in body
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You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if ((j >> i) & 1) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)

EDIT

There is actually another solution to this problem, which I think is better. As we can only let at most one ace in hand to be 11(otherwise the sum will be at least 22, exceeding 21), we just need to check two possibilities: all of the aces are 1, and only one of them is 11.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# All the aces are 1
hand = ace_num + current_hand
if hand <= 21 and hand > ans:
    ans = hand

# Only one ace is 11
if ace_num > 0:
    hand = ace_num-1 + 11 + current_hand
    if hand <= 21 and hand > ans:
        ans = hand

print(ans)

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if ((j >> i) & 1) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if ((j >> i) & 1) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)

EDIT

There is actually another solution to this problem, which I think is better. As we can only let at most one ace in hand to be 11(otherwise the sum will be at least 22, exceeding 21), we just need to check two possibilities: all of the aces are 1, and only one of them is 11.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# All the aces are 1
hand = ace_num + current_hand
if hand <= 21 and hand > ans:
    ans = hand

# Only one ace is 11
if ace_num > 0:
    hand = ace_num-1 + 11 + current_hand
    if hand <= 21 and hand > ans:
        ans = hand

print(ans)
2 added 6 characters in body
source | link

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if ((j >> i) & 1) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if (j >> i) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if ((j >> i) & 1) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)
1
source | link

You can use a binary number to express all the possible hands.

Consider we have 3 aces in hand, so there are 23 = 8 possible hands. We can represent all the 8 possible hands by integers 0~7.

Let's say we want to know the value of a possible hand represented by integer 5(that is 101 in binary form). We check through all the bits of the binary integer, and if the i-th bit is 1, we consider selecting the i-th ace as 11, otherwise we consider selecting the i-th ace as 1. Then the value for possible hand #5(or 101 in binary form) is 11 + 1 + 11 + current_hand_value.

ace_num = 3         # Or whatever number you like
current_hand = 7    # Or whatever number you like
ans = 0

# Enumerate all the possible hands
# Represent each possible hand by a binary number
for i in range(0, 1 << ace_num):
    sum = current_hand

    for j in range(0, ace_num):
        # Decide to pick 1 or 11 according to the j-th bit of the binary number
        if (j >> i) == 1:
            sum += 11
        else:
            sum += 1

    if sum > ans and sum <= 21:
        ans = sum

print(ans)