Spark-ignition direct injection engine

The invention claimed is: 1. A spark-ignition direct injection engine, comprising: an engine body having a cylinder; a fuel injection valve for injecting fuel into the cylinder to form a gas mixture therein; a fuel pressure setting mechanism for setting a pressure of the fuel to be injected by the fuel injection valve; an ignition plug arranged to be oriented toward inside the cylinder and for igniting the gas mixture within the cylinder; and a controller for operating the engine body by controlling at least the fuel injection valve, the fuel pressure setting mechanism, and the ignition plug, wherein the controller switches a combustion mode between a regular compression-ignition mode cycle, with a single, undivided first fuel injection within the regular compression-ignition mode cycle timed at a first fuel injection timing within a predetermined first load range, in which the engine body is operated to perform compression-ignition combustion where the gas mixture within the cylinder self-ignites to combust, and a spark-ignition mode cycle, with a single, undivided second fuel injection within the spark-ignition mode cycle timed at a second fuel injection timing within a predetermined second load range that is other than the first load range, in which the engine body is operated to perform spark-ignition combustion where the ignition plug is controlled to ignite the gas mixture within the cylinder to combust, wherein within the first load range, the controller controls the fuel injection valve to perform the single, undivided first fuel injection within the regular compression-ignition mode cycle at the first fuel injection timing, wherein within the second load range, the controller controls the fuel injection valve to perform the single, undivided second fuel injection within the spark-ignition mode cycle at the second fuel injection timing, wherein during at least one or a plurality of predetermined compression-ignition transitional cycles immediately following the spark-ignition mode cycle and immediately preceding the regular compression-ignition mode cycle, the controller operates the engine body in a compression-ignition initial mode in which fuel pressure is set to be a high fuel pressure of 30 MPa or above by using the fuel pressure setting mechanism and the fuel injection valve is controlled to perform, within the first load range, a single, undivided retarded fuel injection within each predetermined compression-ignition transitional cycle with a retarded fuel injection timing that is retarded later than the first fuel injection timing, so that the retarded fuel injection timing is at least in a period from a late stage of compression stroke to an early stage of expansion stroke so that the gas mixture within the cylinder self-ignites to combust, and after the at least one or a plurality of predetermined compression-ignition transitional cycles ends, the controller controls the engine body to resume performing a fuel injection at the first injection timing within the regular compression-ignition mode cycle, and wherein crank angles of the compression stroke are evenly divided in thirds into an early stage, a middle stage, and the late stage, and crank angles of the expansion stroke are evenly divided in thirds into the early stage, a middle stage, and a late stage. 2. The engine of claim 1 , further comprising an exhaust recirculator for introducing exhaust gas into the cylinder, wherein the controller causes the exhaust recirculator to introduce the exhaust gas into the cylinder in the regular compression-ignition mode cycle to increase an exhaust gas amount within the cylinder, and wherein the controller, during the at least one or a plurality of predetermined compression-ignition transitional cycles in the compression-ignition initial mode, causes the exhaust recirculator to reduce the exhaust gas amount remaining within the cylinder. 3. The engine of claim 1 , wherein the controller advances the fuel injection timing after the compression-ignition initial mode ends. 4. The engine of claim 1 , wherein the controller operates the engine body in the regular compression-ignition mode cycle when an operating state of the engine body is within a predetermined low engine load range, and the controller operates the engine body in the spark-ignition mode cycle when the operating state of the engine body is within a higher engine load range than the predetermined low engine load range, and wherein the controller operates the engine body in the compression-ignition initial mode immediately after the engine load decreases and the operating state of the engine body is shifted from the higher engine load range to the low engine load range. 5. The engine of claim 4 , wherein within a specific low engine load part of the low engine load range where the engine body is operated in the regular compression-ignition mode cycle, the controller controls the fuel injection valve to perform the fuel injection at least in a period from intake stroke to a middle stage of the compression stroke, and wherein the controller operates the engine body in the compression-ignition initial mode immediately after the engine load decreases and the operating state of the engine body is shifted from the higher engine load range to the low engine load range, and the controller advances the fuel injection timing to at least in the period from the intake stroke to the middle stage of the compression stroke immediately after the compression-ignition initial mode ends. 6. The engine of claim 5 , wherein the controller controls the fuel pressure setting mechanism to set the fuel pressure to a low fuel pressure of below 30 MPa when the fuel injection timing is advanced to at least in the period from the intake stroke to the middle stage of the compression stroke immediately after the compression-ignition initial mode ends. 7. The engine of claim 1 , wherein the controller operates the engine body in the regular compression-ignition mode cycle when a temperature of the engine body is in a warmed-up state that is higher than a predetermined temperature, and the controller operates the engine body in the spark-ignition mode cycle when the temperature of the engine body is in a cold-start state that is lower than the predetermined temperature, and wherein the controller operates the engine body in the compression-ignition initial mode immediately after the temperature of the engine body increases and the mode is switched from the spark-ignition mode cycle to the regular compression-ignition mode cycle. 8. The engine of claim 7 , wherein when the temperature of the engine body is in the cold-start state that is lower than the predetermined temperature, the controller controls the fuel pressure setting mechanism to set the fuel pressure to a low fuel pressure of below 30 MPa, controls the fuel injection valve to perform the fuel injection at least in the period from the intake stoke to the middle stage of the compression stroke, and operates the engine body in the spark-ignition mode cycle. 9. A spark-ignition direct injection engine, comprising: an engine body having a cylinder; a fuel injection valve for injecting fuel into the cylinder to form gas mixture therein; a fuel pressure setting mechanism for setting a pressure of the fuel to be injected by the fuel injection valve; an ignition plug arranged to be oriented toward inside the cylinder and for igniting gas mixture within the cylinder; and a controller for operating the engine body by controlling at least the fuel injection valve, the fuel pressure setting mechanism, and the ignition plug, wherein the controller operates, within a predetermined first load range, the engine body in a regular compression-ig