#include "main/simple_list.h"
#include "radeon_dri.h"
-#include "r200_lock.h"
+
+#include "radeon_bocs_wrapper.h"
#include "xf86drm.h"
#include "drm.h"
#include "radeon_drm.h"
-extern void r200EmitState( r200ContextPtr rmesa );
extern void r200EmitVertexAOS( r200ContextPtr rmesa,
GLuint vertex_size,
struct radeon_bo *bo,
GLuint primitive,
GLuint vertex_nr );
-extern void r200FlushElts(r200ContextPtr rmesa);
-
+extern void r200FlushElts(GLcontext *ctx);
extern GLushort *r200AllocEltsOpenEnded( r200ContextPtr rmesa,
GLuint primitive,
extern void r200EmitAOS(r200ContextPtr rmesa, GLuint nr, GLuint offset);
-extern void r200EmitBlit( r200ContextPtr rmesa,
- GLuint color_fmt,
- GLuint src_pitch,
- GLuint src_offset,
- GLuint dst_pitch,
- GLuint dst_offset,
- GLint srcx, GLint srcy,
- GLint dstx, GLint dsty,
- GLuint w, GLuint h );
-
-extern void r200EmitWait( r200ContextPtr rmesa, GLuint flags );
-
-//extern void r200FlushCmdBuf( r200ContextPtr rmesa, const char * );
-//extern int r200FlushCmdBufLocked( r200ContextPtr rmesa, const char * caller );
-
-extern void r200RefillCurrentDmaRegion( r200ContextPtr rmesa );
-
-extern void r200AllocDmaRegion( r200ContextPtr rmesa,
- struct radeon_dma_region *region,
- int bytes,
- int alignment );
-
-extern void r200ReleaseDmaRegion( r200ContextPtr rmesa,
- struct radeon_dma_region *region,
- const char *caller );
-
-extern void r200Flush( GLcontext *ctx );
-extern void r200Finish( GLcontext *ctx );
extern void r200InitIoctlFuncs( struct dd_function_table *functions );
extern void *r200AllocateMemoryMESA( __DRIscreen *screen, GLsizei size, GLfloat readfreq,
*/
#define R200_NEWPRIM( rmesa ) \
do { \
- if ( rmesa->dma.flush ) \
- rmesa->dma.flush( rmesa->radeon.glCtx ); \
+ if ( rmesa->radeon.dma.flush ) \
+ rmesa->radeon.dma.flush( rmesa->radeon.glCtx ); \
} while (0)
/* Can accomodate several state changes and primitive changes without
do { \
R200_NEWPRIM( rmesa ); \
rmesa->hw.ATOM.dirty = GL_TRUE; \
- rmesa->hw.is_dirty = GL_TRUE; \
+ rmesa->radeon.hw.is_dirty = GL_TRUE; \
} while (0)
#define R200_DB_STATE( ATOM ) \
GLuint *tmp;
R200_NEWPRIM( rmesa );
atom->dirty = GL_TRUE;
- rmesa->hw.is_dirty = GL_TRUE;
+ rmesa->radeon.hw.is_dirty = GL_TRUE;
tmp = atom->cmd;
atom->cmd = atom->lastcmd;
atom->lastcmd = tmp;
}
-/* Fire the buffered vertices no matter what.
- */
-#define R200_FIREVERTICES( rmesa ) \
-do { \
- if ( rmesa->store.cmd_used || rmesa->dma.flush ) { \
- r200Flush( rmesa->radeon.glCtx ); \
- } \
-} while (0)
-
/* Command lengths. Note that any time you ensure ELTS_BUFSZ or VBUF_BUFSZ
* are available, you will also be adding an rmesa->state.max_state_size because
* r200EmitState is called from within r200EmitVbufPrim and r200FlushElts.
#define ELTS_BUFSZ(nr) (12 + nr * 2)
#define VBUF_BUFSZ (3 * sizeof(int))
-/* Ensure that a minimum amount of space is available in the command buffer.
- * This is used to ensure atomicity of state updates with the rendering requests
- * that rely on them.
- *
- * An alternative would be to implement a "soft lock" such that when the buffer
- * wraps at an inopportune time, we grab the lock, flush the current buffer,
- * and hang on to the lock until the critical section is finished and we flush
- * the buffer again and unlock.
- */
-#if 0
-static INLINE void r200EnsureCmdBufSpace( r200ContextPtr rmesa, int bytes )
-{
- if (rmesa->store.cmd_used + bytes > R200_CMD_BUF_SZ)
- rcommonFlushCmdBuf( rmesa, __FUNCTION__ );
- assert( bytes <= R200_CMD_BUF_SZ );
-}
-
-/* Alloc space in the command buffer
- */
-static INLINE char *r200AllocCmdBuf( r200ContextPtr rmesa,
- int bytes, const char *where )
-{
- char * head;
-
- if (rmesa->store.cmd_used + bytes > R200_CMD_BUF_SZ)
- r200FlushCmdBuf( rmesa, where );
-
- head = rmesa->store.cmd_buf + rmesa->store.cmd_used;
- rmesa->store.cmd_used += bytes;
- assert( rmesa->store.cmd_used <= R200_CMD_BUF_SZ );
- return head;
-}
-#endif
-
static inline uint32_t cmdpacket3(int cmd_type)
{
drm_radeon_cmd_header_t cmd;