+// Allocate volatiles first, then non-volatiles in reverse order. With the SVR4
+// ABI the size of the Floating-point register save area is determined by the
+// allocated non-volatile register with the lowest register number, as FP
+// register N is spilled to offset 8 * (32 - N) below the back chain word of the
+// previous stack frame. By allocating non-volatiles in reverse order we make
+// sure that the Floating-point register save area is always as small as
+// possible because there aren't any unused spill slots.
+def F8RC : RegisterClass<"PPC", [f64], 64, (add (sequence "F%u", 0, 13),
+ (sequence "F%u", 31, 14))>;
+def F4RC : RegisterClass<"PPC", [f32], 32, (add F8RC)>;
+
+def VRRC : RegisterClass<"PPC", [v16i8,v8i16,v4i32,v2i64,v1i128,v4f32], 128,
+ (add V2, V3, V4, V5, V0, V1, V6, V7, V8, V9, V10, V11,
+ V12, V13, V14, V15, V16, V17, V18, V19, V31, V30,
+ V29, V28, V27, V26, V25, V24, V23, V22, V21, V20)>;
+
+// VSX register classes (the allocation order mirrors that of the corresponding
+// subregister classes).
+def VSLRC : RegisterClass<"PPC", [v4i32,v4f32,v2f64,v2i64], 128,
+ (add (sequence "VSL%u", 0, 13),
+ (sequence "VSL%u", 31, 14))>;
+def VSHRC : RegisterClass<"PPC", [v4i32,v4f32,v2f64,v2i64], 128,
+ (add VSH2, VSH3, VSH4, VSH5, VSH0, VSH1, VSH6, VSH7,
+ VSH8, VSH9, VSH10, VSH11, VSH12, VSH13, VSH14,
+ VSH15, VSH16, VSH17, VSH18, VSH19, VSH31, VSH30,
+ VSH29, VSH28, VSH27, VSH26, VSH25, VSH24, VSH23,
+ VSH22, VSH21, VSH20)>;
+def VSRC : RegisterClass<"PPC", [v4i32,v4f32,v2f64,v2i64], 128,
+ (add VSLRC, VSHRC)>;
+
+// Register classes for the 64-bit "scalar" VSX subregisters.
+def VFRC : RegisterClass<"PPC", [f64], 64,
+ (add VF2, VF3, VF4, VF5, VF0, VF1, VF6, VF7,
+ VF8, VF9, VF10, VF11, VF12, VF13, VF14,
+ VF15, VF16, VF17, VF18, VF19, VF31, VF30,
+ VF29, VF28, VF27, VF26, VF25, VF24, VF23,
+ VF22, VF21, VF20)>;
+def VSFRC : RegisterClass<"PPC", [f64], 64, (add F8RC, VFRC)>;