An information processing method and apparatus in a Virtual Reality (VR) game, and a processor are provided. The method includes that: a first move operation of a VR controller in a real environment is acquired; a move of a virtual object in a VR game scene is controlled according to the first move operation, and a calculation factor is calculated according to the first move operation; and when the move of the virtual object in the VR game scene satisfies a preset attack damage trigger condition, damage to an attack target in the VR game scene is calculated according to the calculation factor. The present disclosure solves technical problems in the related art that an operation mode of swinging a weapon to launch an attack in a VR game scene is easy to cause fatigue of a game player and a calculation mode of damage lacks accuracy.

A collision data processing method includes: determining, based on a physical engine detecting that a first rigid body having a first physical attribute collides with a second rigid body having a second physical attribute, an initial cutting model from a first model corresponding to the first rigid body and a second model corresponding to the second rigid body based on the first physical attribute and the second physical attribute, capturing, by the physical engine, a collision point between the first rigid body and the second rigid body, and determining normal vector information corresponding to the collision point based on collision data, and determining a first cutting surface in the initial cutting model based on the collision point, the normal vector information, and model information of the initial cutting model, and cutting the initial cutting model based on the first cutting surface to obtain cutting data.

A collision data processing method includes: determining, based on a physical engine detecting that a first rigid body having a first physical attribute collides with a second rigid body having a second physical attribute, an initial cutting model from a first model corresponding to the first rigid body and a second model corresponding to the second rigid body based on the first physical attribute and the second physical attribute, capturing, by the physical engine, a collision point between the first rigid body and the second rigid body, and determining normal vector information corresponding to the collision point based on collision data, and determining a first cutting surface in the initial cutting model based on the collision point, the normal vector information, and model information of the initial cutting model, and cutting the initial cutting model based on the first cutting surface to obtain cutting data.

The present disclosure relates to a system and method for constructing an interactive virtual object in a virtual environment implemented in a computer, wherein the computer comprises one or more input devices and one or more output devices providing a user interface allowing a user to interact with the virtual environment, wherein the virtual environment comprises a first virtual construction element carrying a first interactive behavior and a second virtual construction element not carrying the first interactive behavior, wherein the first and second virtual construction elements are connectable to each other by means of a coupling mechanism to form a combined virtual object, and wherein the first virtual construction element imparts the first interactive behavior to the combined virtual object when the first and second construction elements are connected to each other.

The present disclosure relates to a system and method for constructing an interactive virtual object in a virtual environment implemented in a computer, wherein the computer comprises one or more input devices and one or more output devices providing a user interface allowing a user to interact with the virtual environment, wherein the virtual environment comprises a first virtual construction element carrying a first interactive behavior and a second virtual construction element not carrying the first interactive behavior, wherein the first and second virtual construction elements are connectable to each other by means of a coupling mechanism to form a combined virtual object, and wherein the first virtual construction element imparts the first interactive behavior to the combined virtual object when the first and second construction elements are connected to each other.

A method for quasi-random placement of a virtual item in an XR space includes: accessing a previously generated spatial mapping mesh (SMM) of the XR space; compiling a record from the SMM of open spaces between surfaces of physical elements in the XR space, with corresponding positions and dimensions; selecting from the open spaces: a spawn position for a virtual character, and a random set of other positions, filtering the random set to form a subset. The method then performs a collision analysis to assign a score to each position in the subset partly based on accessibility to that position for the virtual character beginning from the spawn position; and places the virtual item at a position in the subset having a score as high or higher than all other positions in the subset. The method is carried out before user interaction with any virtual element in the XR space.

A method for quasi-random placement of a virtual item in an XR space includes: accessing a previously generated spatial mapping mesh (SMM) of the XR space; compiling a record from the SMM of open spaces between surfaces of physical elements in the XR space, with corresponding positions and dimensions; selecting from the open spaces: a spawn position for a virtual character, and a random set of other positions, filtering the random set to form a subset. The method then performs a collision analysis to assign a score to each position in the subset partly based on accessibility to that position for the virtual character beginning from the spawn position; and places the virtual item at a position in the subset having a score as high or higher than all other positions in the subset. The method is carried out before user interaction with any virtual element in the XR space.

A method predefines a virtual staircase connecting real platforms in an XR space by: accessing a previously generated spatial mapping mesh (SMM); compiling a record from the SMM of available surfaces; identifying available platforms provided by the physical elements and available open spaces therebetween; selecting a first platform at a first level and a second platform at a significantly lower level; selecting a staircase start location at a first edge of the first platform, partly based on predetermined criteria; stacking virtual blocks linearly to form a virtual staircase, with a first virtual block contacting and extending outwards from the first platform, and a last virtual block contacting the second platform at a staircase end location; and performing a collision analysis. If the staircase end location satisfies the predetermined criteria, and if no collisions are detected, the current virtual staircase is displayed in subsequent user interactions with the XR space.

A method for regulating falls of a user-controlled character through gaps between surfaces in an extended reality (XR) space in which the user is playing a game includes compiling a record from a previously generated spatial mapping mesh (SMM) of the XR space of surfaces of real elements present in that space, with corresponding positions and dimensions; and, after the game begins, determining whether, if the character approaches a substantially vertical gap between an edge of a first surface at a first level and a second surface, at a second level lower than the first level, continuing motion of the character to fall through the vertical gap will be permitted or prevented. A similar method for regulating jumps rather than falls of a user-controlled character through gaps between surfaces in an extended reality (XR) space in which the user is playing a game is also described.

A method for regulating falls of a user-controlled character through gaps between surfaces in an extended reality (XR) space in which the user is playing a game includes compiling a record from a previously generated spatial mapping mesh (SMM) of the XR space of surfaces of real elements present in that space, with corresponding positions and dimensions; and, after the game begins, determining whether, if the character approaches a substantially vertical gap between an edge of a first surface at a first level and a second surface, at a second level lower than the first level, continuing motion of the character to fall through the vertical gap will be permitted or prevented. A similar method for regulating jumps rather than falls of a user-controlled character through gaps between surfaces in an extended reality (XR) space in which the user is playing a game is also described.