Difference between revisions of "LSL Language Test 2"

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Line 314: Line 314:
      
      
     // Loop for strings
     // Loop for strings
     string s = "1!";
     s = "1!";
     while (s) { s = ""; }  
     while (s) { s = ""; }  
     ensureStringEqual( "while (s) { s = \"\"; }", s, "");
     ensureStringEqual( "while (s) { s = \"\"; }", s, "");

Revision as of 08:30, 18 March 2008

<lsl> integer gTestsPassed = 0; integer gTestsFailed = 0;

key gNullKey = NULL_KEY; key gStringInAKey = "foo";

testPassed(string description, string actual, string expected) {

   ++gTestsPassed;
   //llSay(0, description);

}

testFailed(string description, string actual, string expected) {

   ++gTestsFailed;
   llSay(0, "FAILED!: " + description + " (" + actual + " expected " + expected + ")");

}

ensureTrue(string description, integer actual) {

   if(actual)
   {
       testPassed(description, (string) actual, (string) TRUE);
   }
   else
   {
       testFailed(description, (string) actual, (string) TRUE);
   }

}

ensureFalse(string description, integer actual) {

   if(actual)
   {
       testFailed(description, (string) actual, (string) FALSE);
   }
   else
   {
       testPassed(description, (string) actual, (string) FALSE);
   }

}

ensureIntegerEqual(string description, integer actual, integer expected) {

   if(actual == expected)
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

integer floatEqual(float actual, float expected) {

   float error = llFabs(expected - actual);
   float epsilon = 0.001;
   if(error > epsilon)
   {
       llSay(0,"Float equality delta " + (string)error);
       return FALSE;
   }
   return TRUE;

}

ensureFloatEqual(string description, float actual, float expected) {

   if(floatEqual(actual, expected))
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureFloatExactEqual(string description, float actual, float expected) {

   if(actual == expected)
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureStringEqual(string description, string actual, string expected) {

   if(actual == expected)
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureKeyEqual(string description, key actual, key expected) {

   if(actual == expected)
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureVectorEqual(string description, vector actual, vector expected) {

   if(floatEqual(actual.x, expected.x) &&
       floatEqual(actual.y, expected.y) &&
       floatEqual(actual.z, expected.z))
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureRotationEqual(string description, rotation actual, rotation expected) {

   if(floatEqual(actual.x, expected.x) &&
       floatEqual(actual.y, expected.y) &&
       floatEqual(actual.z, expected.z) &&
       floatEqual(actual.s, expected.s))
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

ensureListEqual(string description, list actual, list expected) {

   if(actual == expected)
   {
       testPassed(description, (string) actual, (string) expected);
   }
   else
   {
       testFailed(description, (string) actual, (string) expected);
   }

}

vector gVector;

float testReturnFloat() {

   return 1.0;

}

testArgumentAccessor(vector v) {

   v = <0,0,0>;
   v.x = testReturnFloat();
   v.y = testReturnFloat();
   v.z = testReturnFloat();
   ensureVectorEqual("testArgumentAccessor", v, <1,1,1>);

}

testLocalAccessor() {

   vector v = <0,0,0>;
   v.x = testReturnFloat();
   v.y = testReturnFloat();
   v.z = testReturnFloat();
   ensureVectorEqual("testLocalAccessor", v, <1,1,1>);

}

testGlobalAccessor() {

   gVector = <0,0,0>;
   gVector.x = testReturnFloat();
   gVector.y = testReturnFloat();
   gVector.z = testReturnFloat();
   ensureVectorEqual("testGlobalAccessor", gVector, <1,1,1>);

}

tests() {

   ensureFloatExactEqual("1.4e-45 == (float)\"1.4e-45\"", 1.4e-45, (float)"1.4e-45");

   // Managed pointer save/restore tests.
   testArgumentAccessor(<0,0,0>);
   testLocalAccessor();
   testGlobalAccessor();

   // Multiple list element saving (SVC-1712 Regression)
   ensureStringEqual("(string)[1, testReturnFloat(), testReturnFloat()] == \"11.01.0\"", (string)[1, testReturnFloat(), testReturnFloat()], "11.0000001.000000");

   // Key equality (SVC-1720 Regression)
   key k = "foo";
   key k2 = "foo";
   ensureKeyEqual("k = \"foo\";k2 = \"foo\";k == k2", k, k2);

   // List comparison. Not actual comparison, just length.
   ensureIntegerEqual("[] == []", [] == [], 1);
   ensureIntegerEqual("[1] == [2]", [1] == [2], 1);
   ensureIntegerEqual("[1,2] == [1,2]", [1,2] == [1,2], 1);
   ensureIntegerEqual("[1,2] == [2]", [1,2] == [2], 0);
   ensureIntegerEqual("[1] == [2,3]", [1] == [2,3], 0);

   ensureIntegerEqual("[] != []", [] != [], 0);
   ensureIntegerEqual("[1] != [2]", [1] != [2], 0);
   ensureIntegerEqual("[1,2] != [1,2]", [1,2] != [1,2], 0);
   ensureIntegerEqual("[1,2] != [2]", [1,2] != [2], 1);
   ensureIntegerEqual("[1] != [2,3]", [1] != [2,3], -1);

   // Parsing numbers with junk after
   ensureFloatEqual("(float)\"5.0a\" == 5.0", (float) "5a", 5.0);
   ensureFloatEqual("(integer)\"12foo\" == 12", (integer) "12foo", 12);

   // List value semantics across addition (SVC-1448 Regression)
   list l;
   l = [42];
   l + 1;
   ensureListEqual("list l = [42]; l + 1; l == [42]", l, [42]);
   l = [42];
   l + 1.5;
   ensureListEqual("list l = [42]; l + 1.5; l == [42]", l, [42]);
   l = [42];
   l + NULL_KEY;
   ensureListEqual("list l = [42]; l + NULL_KEY; l == [42]", l, [42]);
   l = [42];
   l + <1,2,3>;    
   ensureListEqual("list l = [42]; l + <1,2,3>; l == [42]", l, [42]);
   l = [42];
   l + <1,2,3,4>;    
   ensureListEqual("list l = [42]; l + <1,2,3>; l == [42]", l, [42]);


   // Conditional test of key (SVC-1776/SVC-1811 Regression)
   if(k)
   {
       testFailed("if(k)", "TRUE", "FALSE");
   }
   else
   {
       testPassed("if(k)", "FALSE", "FALSE");
   }

   // String/Key equality (SVC-1770 Regression)
   ensureIntegerEqual("k == \"foo\"",k == "foo", TRUE);

   // String/Key equality (SVC-1772 Regression)
   ensureIntegerEqual("gStringInAKey == \"foo\"", gStringInAKey == "foo", TRUE);
   ensureIntegerEqual("gNullKey == NULL_KEY", gNullKey == NULL_KEY, TRUE);
   // Key to string cast on assignment (SVC-1707 Regression)
   k = NULL_KEY;
   string s;
   s = k;
   ensureStringEqual("k = NULL_KEY; string s; s = k;", s, NULL_KEY);
   // Loop semantics for vectors
   vector v = <1,1,1>;
   while (v) { v = ZERO_VECTOR; } 
   ensureVectorEqual( "while (v) { v = ZERO_VECTOR; }", v, ZERO_VECTOR);
   
   v = <2,2,2>;
   do {  v = ZERO_VECTOR; } while (v);   
   ensureVectorEqual( "v = <2,2,2>; do { v = ZERO_VECTOR } while (v);", v, ZERO_VECTOR);
   
   for (v = <3,3,3>;v;v=ZERO_VECTOR) {}
   ensureVectorEqual( "for (v = <3,3,3>;v;v=ZERO_VECTOR) {}", v, ZERO_VECTOR);
   
   // Loops with keys
   k = "7c42811e-229f-4500-b6d7-2c37324ff816";
   while (k) { k = NULL_KEY; } 
   ensureKeyEqual( "while (k) { k = NULL_KEY; }", k, NULL_KEY);
   
   k = "7c42811e-229f-4500-b6d7-2c37324ff816";
   do {  k = NULL_KEY; } while (k);   
   ensureKeyEqual( "k = \"7c42811e-229f-4500-b6d7-2c37324ff816\"; do { k = NULL_KEY } while (k);", k, NULL_KEY);
   
   for (k = "7c42811e-229f-4500-b6d7-2c37324ff816"; k; k=NULL_KEY) {}
   ensureKeyEqual( "for (k = \"7c42811e-229f-4500-b6d7-2c37324ff816\";k;k=NULL_KEY) {}", k, NULL_KEY);  

   // Loops with rotations
   rotation q = <1,1,1,1>;
   while (q) { q = ZERO_ROTATION; } 
   ensureRotationEqual( "while (q) { q = ZERO_ROTATION; }", q, ZERO_ROTATION);
   
   q = <2,2,2,2>;
   do {  q = ZERO_ROTATION; } while (q);   
   ensureRotationEqual( "q = <2,2,2>; do { v = ZERO_ROTATION } while (q);", q, ZERO_ROTATION);
   
   for (q = <3,3,3,3>; q; q=ZERO_ROTATION) {}
   ensureRotationEqual( "for (q = <3,3,3,3>;q;q=ZERO_ROTATION) {}", q, ZERO_ROTATION);    
   
   // Loops with lists
   l = [1];
   while (l) { l = []; } 
   ensureListEqual( "while (l) { l = []; }", l, []); // Fails on LSL
   
   l = [2];
   do { l = []; } while (l);   
   ensureListEqual( "l = [2]; do { v = [] } while (l);", l, []);
   
   for (l = [3]; l; l=[]) {}
   ensureListEqual( "for (l = [3];l;l=[]) {}", l, []);  // Fails on LSL   
   
   // Loop for strings
   s = "1!";
   while (s) { s = ""; } 
   ensureStringEqual( "while (s) { s = \"\"; }", s, "");
   
   s = "2!";
   do {  s = ""; } while (s);   
   ensureStringEqual( "s = \"2!\"; do { s = \"\" } while (s);", s, "");
   
   for (s = "3!";s;s="") {}
   ensureStringEqual( "for (s = \"3!\";s;s=\"\") {}", s, "");
   
   // Loop for integers
   integer i = 1;
   while (i) { i = 0; } 
   ensureIntegerEqual( "while (i) { i = 0; }", i, 0);
   
   i = 2;
   do {  i = 0; } while (i);   
   ensureIntegerEqual( "i = 2; do { i = 0 } while (i);", i, 0);
   
   for (i = 3;i;i=0) {}
   ensureIntegerEqual( "for (i = 3;i;i=0) {}", i, 0);    
   
   // Loop for floats
   float f = 1;
   while (f) { f = 0; } 
   ensureFloatEqual( "while (f) { f = 0; }", f, 0);
   
   f = 2;
   do {  f = 0; } while (f);   
   ensureFloatEqual( "f = 2; do { f = 0 } while (f);", f, 0);
   
   for (f = 3;f;f=0) {}
   ensureFloatEqual( "for (f = 3;f;f=0) {}", f, 0);        

}

runTests() {

   llResetTime();
   tests();
   llSay(0, "Ran " + (string)(gTestsPassed + gTestsFailed) + " tests in " + (string) llGetTime() + " seconds with " + (string)gTestsFailed + " failures");
   gTestsPassed = 0;
   gTestsFailed = 0;

}

default {

   state_entry()
   {
       runTests();
   }

   touch_start(integer total_number)
   {
       runTests();
   }

} </lsl>