From 317b8a1a9cd5dd8cab99827bb9c66b320d888bdf Mon Sep 17 00:00:00 2001
From: Mukendi Mputu <mukendi_mputu@outlook.com>
Date: Thu, 30 Jun 2022 14:06:36 +0200
Subject: [PATCH] state before helpDesk

---
 schedTests/TimeDemandAnalysis.py | 39 ++++++++++++++++++++------------
 1 file changed, 24 insertions(+), 15 deletions(-)

diff --git a/schedTests/TimeDemandAnalysis.py b/schedTests/TimeDemandAnalysis.py
index 5833180..b0b0760 100644
--- a/schedTests/TimeDemandAnalysis.py
+++ b/schedTests/TimeDemandAnalysis.py
@@ -14,15 +14,18 @@ import include.TasksHelper as TH
 # The number of tasks can be accessed as: tasks.shape[0]
 
 # The Time Demand Analysis Test
-
+set_num = 0
 
 def test(tasks):
     # Sorting Taskset by Period/Deadline
     # This makes implementing TDA a lot easier
     shape = tasks.shape
     sortedtasks = tasks[tasks[:, 0].argsort()]
+    isSchedulable = True
+    global set_num 
+    set_num += 1
 
-    print("\n======= TASK SET =======")
+    print(f"\n======= TASK SET #{set_num} =======\n")
     # For each tasks in the ordered set
     for i in range(len(sortedtasks)):
 
@@ -30,25 +33,31 @@ def test(tasks):
 
         # calculate the time points for the demand function
         # t = j * P_k for k = 1, 2,...i and j = 1, 2,...,math.ceil(P_i / P_k)
-        list_of_t = [TH.P_i(sortedtasks, k) * j for k in range(1, i)
-                     for j in range(1, int(np.ceil(TH.D_i(sortedtasks, i) / TH.P_i(sortedtasks, k))))]
+        # list_of_t = [
+        #    j * TH.P_i(sortedtasks, k)
+        #    for k in range(i-1) 
+        #    for j in range(1, int(math.ceil(TH.D_i(sortedtasks, i) / TH.P_i(sortedtasks, k))))
+        #    ]
+        # list_of_t = [TH.P_i(sortedtasks, k-1) for k in range(i+1)]
+        list_of_t = []
+        for k in range(i):
+            list_of_t.append(TH.P_i(sortedtasks, k-1))
 
-        # print(f'\t list of ts: {list_of_t}')
+        print(f'\t list of t: {list_of_t}')
 
         # at any time t between 0 and and TH.P_i
-        for t in np.sort(list_of_t):
-        # for t in range(TH.C_i(sortedtasks, i), TH.P_i(sortedtasks, i)+1, TH.P_i(sortedtasks, i)):
-
-            print(f'\tTime-Demand for t ({t}): {time_demand_func(sortedtasks, i, t)} ')
+        for j in range(len(list_of_t)):
+        # for t in range(int(TH.C_i(sortedtasks, i)), int(TH.P_i(sortedtasks, i)+1), int(step)):
 
             # if the demand for CPU time of task i exceeds the available time t
-            if time_demand_func(sortedtasks, i, t) > t:
-                return False # then the task i will not meet its deadline, hence taskset not schedulable
-    return True
+            if time_demand_func(sortedtasks, i, list_of_t[j]) > list_of_t[j]:
+                isSchedulable = False # then the task i will not meet its deadline, hence taskset not schedulable
+            print(f'\t time-demand for t := {list_of_t[j]} ---> {time_demand_func(sortedtasks, i, list_of_t[j])}  is schedulable: {isSchedulable}')
+    return isSchedulable
 
 
-def time_demand_func(tasks, i, delta=0):
+def time_demand_func(tasks, i, t):
     sum = 0
-    for k in range(1, i-1):
-        sum += math.ceil(delta / TH.P_i(tasks, k)) * TH.C_i(tasks, k)
+    for k in range(i-1):
+        sum += math.ceil(t / TH.P_i(tasks, k)) * TH.C_i(tasks, k)
     return TH.C_i(tasks, i) + sum