all: Update Python formatting to latest Black version 22.1.0.

Signed-off-by: Damien George <damien@micropython.org>

examples/rp2/pio_pwm.py

@@ -41,5 +41,5 @@ pwm = PIOPWM(0, 25, max_count=(1 << 16) - 1, count_freq=10_000_000)
 
 while True:
     for i in range(256):
-        pwm.set(i ** 2)
+        pwm.set(i**2)
         sleep(0.01)

tests/cpydiff/modules_random_randint.py

@@ -8,5 +8,5 @@ workaround: If you need integers larger than native wordsize use the random modu
 import random
 
 
-x = random.randint(2 ** 128 - 1, 2 ** 128)
+x = random.randint(2**128 - 1, 2**128)
 print("x={}".format(x))

tests/float/complex1.py

@@ -27,15 +27,15 @@ print(1j * 2j)
 print(1j / 2)
 print((1j / 2j).real)
 print(1j / (1 + 2j))
-ans = 0j ** 0
+ans = 0j**0
 print("%.5g %.5g" % (ans.real, ans.imag))
-ans = 0j ** 1
+ans = 0j**1
 print("%.5g %.5g" % (ans.real, ans.imag))
-ans = 0j ** 0j
+ans = 0j**0j
 print("%.5g %.5g" % (ans.real, ans.imag))
-ans = 1j ** 2.5
+ans = 1j**2.5
 print("%.5g %.5g" % (ans.real, ans.imag))
-ans = 1j ** 2.5j
+ans = 1j**2.5j
 print("%.5g %.5g" % (ans.real, ans.imag))
 
 # comparison
@@ -116,10 +116,10 @@ except ZeroDivisionError:
 
 # zero division via power
 try:
-    0j ** -1
+    0j**-1
 except ZeroDivisionError:
     print("ZeroDivisionError")
 try:
-    0j ** 1j
+    0j**1j
 except ZeroDivisionError:
     print("ZeroDivisionError")

tests/float/float1.py

@@ -88,7 +88,7 @@ except ZeroDivisionError:
     print("ZeroDivisionError")
 
 try:
-    0.0 ** -1
+    0.0**-1
 except ZeroDivisionError:
     print("ZeroDivisionError")
 

tests/float/float2int_doubleprec_intbig.py

@@ -35,8 +35,8 @@ if ll_type != 0:
     print(int(1418774543.0))
     print("%d" % 1418774543.0)
     if ll_type == 3:
-        print(int(2.0 ** 100))
-        print("%d" % 2.0 ** 100)
+        print(int(2.0**100))
+        print("%d" % 2.0**100)
 else:
     print(int(1073741823.0))
     print("%d" % 1073741823.0)
@@ -44,7 +44,7 @@ else:
 testpass = True
 p2_rng = ((30, 63, 1024), (62, 63, 1024))[is_64bit][ll_type]
 for i in range(0, p2_rng):
-    bitcnt = len(bin(int(2.0 ** i))) - 3
+    bitcnt = len(bin(int(2.0**i))) - 3
     if i != bitcnt:
         print("fail: 2**%u was %u bits long" % (i, bitcnt))
         testpass = False
@@ -53,7 +53,7 @@ print("power of  2 test: %s" % (testpass and "passed" or "failed"))
 testpass = True
 p10_rng = ((9, 18, 23), (18, 18, 23))[is_64bit][ll_type]
 for i in range(0, p10_rng):
-    digcnt = len(str(int(10.0 ** i))) - 1
+    digcnt = len(str(int(10.0**i))) - 1
     if i != digcnt:
         print("fail: 10**%u was %u digits long" % (i, digcnt))
         testpass = False
@@ -72,28 +72,28 @@ def fp2int_test(num, name, should_fail):
 if ll_type != 2:
     if ll_type == 0:
         if is_64bit:
-            neg_bad_fp = -1.00000005 * 2.0 ** 62.0
-            pos_bad_fp = 2.0 ** 62.0
-            neg_good_fp = -(2.0 ** 62.0)
-            pos_good_fp = 0.99999993 * 2.0 ** 62.0
+            neg_bad_fp = -1.00000005 * 2.0**62.0
+            pos_bad_fp = 2.0**62.0
+            neg_good_fp = -(2.0**62.0)
+            pos_good_fp = 0.99999993 * 2.0**62.0
         else:
-            neg_bad_fp = -1.00000005 * 2.0 ** 30.0
-            pos_bad_fp = 2.0 ** 30.0
-            neg_good_fp = -(2.0 ** 30.0)
-            pos_good_fp = 0.9999999499 * 2.0 ** 30.0
+            neg_bad_fp = -1.00000005 * 2.0**30.0
+            pos_bad_fp = 2.0**30.0
+            neg_good_fp = -(2.0**30.0)
+            pos_good_fp = 0.9999999499 * 2.0**30.0
     else:
-        neg_bad_fp = -0.51 * 2.0 ** 64.0
-        pos_bad_fp = 2.0 ** 63.0
-        neg_good_fp = -(2.0 ** 63.0)
-        pos_good_fp = 1.9999998 * 2.0 ** 62.0
+        neg_bad_fp = -0.51 * 2.0**64.0
+        pos_bad_fp = 2.0**63.0
+        neg_good_fp = -(2.0**63.0)
+        pos_good_fp = 1.9999998 * 2.0**62.0
 
     fp2int_test(neg_bad_fp, "neg bad", True)
     fp2int_test(pos_bad_fp, "pos bad", True)
     fp2int_test(neg_good_fp, "neg good", False)
     fp2int_test(pos_good_fp, "pos good", False)
 else:
-    fp2int_test(-1.9999999999999981 * 2.0 ** 1023.0, "large neg", False)
-    fp2int_test(1.9999999999999981 * 2.0 ** 1023.0, "large pos", False)
+    fp2int_test(-1.9999999999999981 * 2.0**1023.0, "large neg", False)
+    fp2int_test(1.9999999999999981 * 2.0**1023.0, "large pos", False)
 
 fp2int_test(float("inf"), "inf test", True)
 fp2int_test(float("-inf"), "inf test", True)

tests/float/float2int_fp30_intbig.py

@@ -34,13 +34,13 @@ if ll_type is None:
 print(int(14187744.0))
 print("%d" % 14187744.0)
 if ll_type == 2:
-    print(int(2.0 ** 100))
-    print("%d" % 2.0 ** 100)
+    print(int(2.0**100))
+    print("%d" % 2.0**100)
 
 testpass = True
 p2_rng = ((30, 63, 127), (62, 63, 127))[is_64bit][ll_type]
 for i in range(0, p2_rng):
-    bitcnt = len(bin(int(2.0 ** i))) - 3
+    bitcnt = len(bin(int(2.0**i))) - 3
     if i != bitcnt:
         print("fail: 2.**%u was %u bits long" % (i, bitcnt))
         testpass = False
@@ -50,7 +50,7 @@ print("power of  2 test: %s" % (testpass and "passed" or "failed"))
 testpass = True
 p10_rng = 9
 for i in range(0, p10_rng):
-    digcnt = len(str(int(10.0 ** i))) - 1
+    digcnt = len(str(int(10.0**i))) - 1
     if i != digcnt:
         print("fail: 10.**%u was %u digits long" % (i, digcnt))
         testpass = False
@@ -69,28 +69,28 @@ def fp2int_test(num, name, should_fail):
 if ll_type != 2:
     if ll_type == 0:
         if is_64bit:
-            neg_bad_fp = -1.00000005 * 2.0 ** 62.0
-            pos_bad_fp = 2.0 ** 62.0
-            neg_good_fp = -(2.0 ** 62.0)
-            pos_good_fp = 0.99999993 * 2.0 ** 62.0
+            neg_bad_fp = -1.00000005 * 2.0**62.0
+            pos_bad_fp = 2.0**62.0
+            neg_good_fp = -(2.0**62.0)
+            pos_good_fp = 0.99999993 * 2.0**62.0
         else:
-            neg_bad_fp = -1.00000005 * 2.0 ** 30.0
-            pos_bad_fp = 2.0 ** 30.0
-            neg_good_fp = -(2.0 ** 30.0)
-            pos_good_fp = 0.9999999499 * 2.0 ** 30.0
+            neg_bad_fp = -1.00000005 * 2.0**30.0
+            pos_bad_fp = 2.0**30.0
+            neg_good_fp = -(2.0**30.0)
+            pos_good_fp = 0.9999999499 * 2.0**30.0
     else:
-        neg_bad_fp = -0.51 * 2.0 ** 64.0
-        pos_bad_fp = 2.0 ** 63.0
-        neg_good_fp = -(2.0 ** 63.0)
-        pos_good_fp = 1.9999998 * 2.0 ** 62.0
+        neg_bad_fp = -0.51 * 2.0**64.0
+        pos_bad_fp = 2.0**63.0
+        neg_good_fp = -(2.0**63.0)
+        pos_good_fp = 1.9999998 * 2.0**62.0
 
     fp2int_test(neg_bad_fp, "neg bad", True)
     fp2int_test(pos_bad_fp, "pos bad", True)
     fp2int_test(neg_good_fp, "neg good", False)
     fp2int_test(pos_good_fp, "pos good", False)
 else:
-    fp2int_test(-1.999999879 * 2.0 ** 126.0, "large neg", False)
-    fp2int_test(1.999999879 * 2.0 ** 126.0, "large pos", False)
+    fp2int_test(-1.999999879 * 2.0**126.0, "large neg", False)
+    fp2int_test(1.999999879 * 2.0**126.0, "large pos", False)
 
 fp2int_test(float("inf"), "inf test", True)
 fp2int_test(float("-inf"), "inf test", True)

tests/float/float2int_intbig.py

@@ -37,13 +37,13 @@ print(int(14187745.))
 print("%d" % 14187745.)
 # fmt: on
 if ll_type == 2:
-    print(int(2.0 ** 100))
-    print("%d" % 2.0 ** 100)
+    print(int(2.0**100))
+    print("%d" % 2.0**100)
 
 testpass = True
 p2_rng = ((30, 63, 127), (62, 63, 127))[is_64bit][ll_type]
 for i in range(0, p2_rng):
-    bitcnt = len(bin(int(2.0 ** i))) - 3
+    bitcnt = len(bin(int(2.0**i))) - 3
     if i != bitcnt:
         print("fail: 2.**%u was %u bits long" % (i, bitcnt))
         testpass = False
@@ -53,7 +53,7 @@ print("power of  2 test: %s" % (testpass and "passed" or "failed"))
 testpass = True
 p10_rng = 9 if (ll_type == 0 and ~is_64bit) else 11
 for i in range(0, p10_rng):
-    digcnt = len(str(int(10.0 ** i))) - 1
+    digcnt = len(str(int(10.0**i))) - 1
     if i != digcnt:
         print("fail: 10.**%u was %u digits long" % (i, digcnt))
         testpass = False
@@ -72,28 +72,28 @@ def fp2int_test(num, name, should_fail):
 if ll_type != 2:
     if ll_type == 0:
         if is_64bit:
-            neg_bad_fp = -1.00000005 * 2.0 ** 62.0
-            pos_bad_fp = 2.0 ** 62.0
-            neg_good_fp = -(2.0 ** 62.0)
-            pos_good_fp = 0.99999993 * 2.0 ** 62.0
+            neg_bad_fp = -1.00000005 * 2.0**62.0
+            pos_bad_fp = 2.0**62.0
+            neg_good_fp = -(2.0**62.0)
+            pos_good_fp = 0.99999993 * 2.0**62.0
         else:
-            neg_bad_fp = -1.00000005 * 2.0 ** 30.0
-            pos_bad_fp = 2.0 ** 30.0
-            neg_good_fp = -(2.0 ** 30.0)
-            pos_good_fp = 0.9999999499 * 2.0 ** 30.0
+            neg_bad_fp = -1.00000005 * 2.0**30.0
+            pos_bad_fp = 2.0**30.0
+            neg_good_fp = -(2.0**30.0)
+            pos_good_fp = 0.9999999499 * 2.0**30.0
     else:
-        neg_bad_fp = -0.51 * 2.0 ** 64.0
-        pos_bad_fp = 2.0 ** 63.0
-        neg_good_fp = -(2.0 ** 63.0)
-        pos_good_fp = 1.9999998 * 2.0 ** 62.0
+        neg_bad_fp = -0.51 * 2.0**64.0
+        pos_bad_fp = 2.0**63.0
+        neg_good_fp = -(2.0**63.0)
+        pos_good_fp = 1.9999998 * 2.0**62.0
 
     fp2int_test(neg_bad_fp, "neg bad", True)
     fp2int_test(pos_bad_fp, "pos bad", True)
     fp2int_test(neg_good_fp, "neg good", False)
     fp2int_test(pos_good_fp, "pos good", False)
 else:
-    fp2int_test(-1.999999879 * 2.0 ** 127.0, "large neg", False)
-    fp2int_test(1.999999879 * 2.0 ** 127.0, "large pos", False)
+    fp2int_test(-1.999999879 * 2.0**127.0, "large neg", False)
+    fp2int_test(1.999999879 * 2.0**127.0, "large pos", False)
 
 fp2int_test(float("inf"), "inf test", True)
 fp2int_test(float("nan"), "NaN test", True)

tests/float/inf_nan_arith.py

@@ -14,7 +14,7 @@ for x in values:
         except ZeroDivisionError:
             print("  / ZeroDivisionError")
         try:
-            print("  ** pow", x ** y, pow(x, y))
+            print("  ** pow", x**y, pow(x, y))
         except ZeroDivisionError:
             print("  ** pow ZeroDivisionError")
         print("  == != < <= > >=", x == y, x != y, x < y, x <= y, x > y, x >= y)

tests/float/int_big_float.py

@@ -19,7 +19,7 @@ print("%.5g" % (i / 1.2))
 print("%.5g" % (i * 1.2j).imag)
 
 # negative power should produce float
-print("%.5g" % (i ** -1))
+print("%.5g" % (i**-1))
 print("%.5g" % ((2 + i - i) ** -3))
 
 try:

tests/float/int_divzero.py

@@ -4,6 +4,6 @@ except ZeroDivisionError:
     print("ZeroDivisionError")
 
 try:
-    0 ** -1
+    0**-1
 except ZeroDivisionError:
     print("ZeroDivisionError")

tests/float/int_power.py

@@ -1,7 +1,7 @@
 # negative power should produce float
 
 x = 2
-print(x ** -2)
+print(x**-2)
 
 x = 3
 x **= -2

tests/micropython/import_mpy_native_x64.py

@@ -9,7 +9,7 @@ except (ImportError, AttributeError):
     print("SKIP")
     raise SystemExit
 
-if not (usys.platform == "linux" and usys.maxsize > 2 ** 32):
+if not (usys.platform == "linux" and usys.maxsize > 2**32):
     print("SKIP")
     raise SystemExit
 

tests/misc/rge_sm.py

@@ -52,12 +52,12 @@ class RungeKutta(object):
 # couplings are: g1, g2, g3 of U(1), SU(2), SU(3); yt (top Yukawa), lambda (Higgs quartic)
 # see arxiv.org/abs/0812.4950, eqs 10-15
 sysSM = (
-    lambda *a: 41.0 / 96.0 / math.pi ** 2 * a[1] ** 3,  # g1
-    lambda *a: -19.0 / 96.0 / math.pi ** 2 * a[2] ** 3,  # g2
-    lambda *a: -42.0 / 96.0 / math.pi ** 2 * a[3] ** 3,  # g3
+    lambda *a: 41.0 / 96.0 / math.pi**2 * a[1] ** 3,  # g1
+    lambda *a: -19.0 / 96.0 / math.pi**2 * a[2] ** 3,  # g2
+    lambda *a: -42.0 / 96.0 / math.pi**2 * a[3] ** 3,  # g3
     lambda *a: 1.0
     / 16.0
-    / math.pi ** 2
+    / math.pi**2
     * (
         9.0 / 2.0 * a[4] ** 3
         - 8.0 * a[3] ** 2 * a[4]
@@ -66,7 +66,7 @@ sysSM = (
     ),  # yt
     lambda *a: 1.0
     / 16.0
-    / math.pi ** 2
+    / math.pi**2
     * (
         24.0 * a[5] ** 2
         + 12.0 * a[4] ** 2 * a[5]
@@ -137,5 +137,5 @@ def singleTraj(system, trajStart, h=0.02, tend=1.0):
 
 # initial conditions at M_Z
 singleTraj(
-    sysSM, [0.354, 0.654, 1.278, 0.983, 0.131], h=0.5, tend=math.log(10 ** 17)
+    sysSM, [0.354, 0.654, 1.278, 0.983, 0.131], h=0.5, tend=math.log(10**17)
 )  # true values

tests/perf_bench/bm_chaos.py

@@ -15,7 +15,7 @@ class GVector(object):
         self.z = z
 
     def Mag(self):
-        return math.sqrt(self.x ** 2 + self.y ** 2 + self.z ** 2)
+        return math.sqrt(self.x**2 + self.y**2 + self.z**2)
 
     def dist(self, other):
         return math.sqrt(

tests/perf_bench/misc_raytrace.py

@@ -22,7 +22,7 @@ class Vec:
         return Vec(self.x * rhs, self.y * rhs, self.z * rhs)
 
     def length(self):
-        return (self.x ** 2 + self.y ** 2 + self.z ** 2) ** 0.5
+        return (self.x**2 + self.y**2 + self.z**2) ** 0.5
 
     def normalise(self):
         l = self.length()
@@ -87,12 +87,12 @@ class Sphere:
     def __init__(self, surface, centre, radius):
         self.surface = surface
         self.centre = centre
-        self.radsq = radius ** 2
+        self.radsq = radius**2
 
     def intersect(self, ray):
         v = self.centre - ray.p
         b = v.dot(ray.d)
-        det = b ** 2 - v.dot(v) + self.radsq
+        det = b**2 - v.dot(v) + self.radsq
         if det > 0:
             det **= 0.5
             t1 = b - det
@@ -180,7 +180,7 @@ def trace_ray(scene, ray, depth):
         if ndotl > 0:
             col += light_col * surf.diffuse * ndotl
         if ldotv > 0:
-            col += light_col * surf.specular * ldotv ** surf.spec_idx
+            col += light_col * surf.specular * ldotv**surf.spec_idx
 
     # Reflections
     if depth > 0 and surf.reflect > 0:

tests/run-perfbench.py

@@ -33,8 +33,8 @@ def compute_stats(lst):
         avg += x
         var += x * x
     avg /= len(lst)
-    var = max(0, var / len(lst) - avg ** 2)
-    return avg, var ** 0.5
+    var = max(0, var / len(lst) - avg**2)
+    return avg, var**0.5
 
 
 def run_script_on_target(target, script):
@@ -201,7 +201,7 @@ def compute_diff(file1, file2, diff_score):
             sd1 *= av1 / 100  # convert from percent sd to absolute sd
             sd2 *= av2 / 100  # convert from percent sd to absolute sd
             av_diff = av2 - av1
-            sd_diff = (sd1 ** 2 + sd2 ** 2) ** 0.5
+            sd_diff = (sd1**2 + sd2**2) ** 0.5
             percent = 100 * av_diff / av1
             percent_sd = 100 * sd_diff / av1
             print(