I am sharing this figure I drew, in case this can help you to clearly understand what is going on and build a more optimal algorithm.

This is the pseudo code:

**Cp** is a **positive counter**: increase it when going uphill

**Cn** is a **negative counter**: increase it when going downhill

Reset **Cp** and **Cn** when **moving horizontally,** or when we have **reach** a **valley** (Opposite of a Peak).

If **array[i] > array[i-1]** and **array[i] > array[i+1]**, then **array[i]** is a **peak**. The opposite of this statement can be used to find when we reach a **valley**

After we reach the peak, keep incrementing Cn (Cn += 1) until an eventual reset of Cn.

Right before resetting Cn to zero, set **peak_length = Cp+Cn**. If we reached the end of the array and no reset is made, then the peak length is **Cp+Cn**.

Calculate the **max** of the different peak_length

**And Here is the Python code**

```
def peaks_and_valleys(A):
Cp, Cn = 0, 0
longest_path = 0
peak_dict = {} # Track and save the peaks and their length
valley = [] # This is just to track and save the valleys
N = len(A)
for i in range(N-2):
if A[i+1] > A[i]: # Uphill
Cp += 1
if (A[i+1] == A[i+2]): # Uphill and Flat
Cp, Cn = 0, 0
if (A[i+1] > A[i]) and (A[i+1] > A[i+2]): # Peak
peak = A[i+1] # Record and save the peaks
# Keep incrementing negative counter while going Downhill
while i< N-2 and A[i+1] > A[i+2]:
Cn += 1
i += 1
# At the end of the peak, calculate the longest path
longest_path = max(longest_path, Cp+Cn+1)
peak_dict[peak] = longest_path # Track the peaks
elif A[i+1] < A[i]: # Downhill
Cn += 1
if A[i+1] < A[i+2]: # Valley
valley.append(A[i+1]) # Save the Valleys
Cp, Cn = 0, 0
elif (A[i+1] == A[i]) : # Flat
Cp, Cn = 0, 0
print("{Peak': 'Peak Lenght}")
print(peak_dict)
print("valley",valley)
return longest_path
```

`000011110000`

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