}
}
+bool pa_setup_remap_arrange(const pa_remap_t *m, int8_t arrange[PA_CHANNELS_MAX]) {
+ unsigned ic, oc;
+ unsigned n_ic, n_oc;
+
+ pa_assert(m);
+
+ n_ic = m->i_ss.channels;
+ n_oc = m->o_ss.channels;
+
+ for (oc = 0; oc < n_oc; oc++) {
+ arrange[oc] = -1;
+ for (ic = 0; ic < n_ic; ic++) {
+ int32_t vol = m->map_table_i[oc][ic];
+
+ /* input channel is not used */
+ if (vol == 0)
+ continue;
+
+ /* if mixing this channel, we cannot just rearrange */
+ if (vol != 0x10000 || arrange[oc] >= 0)
+ return false;
+
+ arrange[oc] = ic;
+ }
+ }
+
+ return true;
+}
+
/* set the function that will execute the remapping based on the matrices */
static void init_remap_c(pa_remap_t *m) {
unsigned n_oc, n_ic;
pa_init_remap_func_t pa_get_init_remap_func(void);
void pa_set_init_remap_func(pa_init_remap_func_t func);
+/* Check if remapping can be performed by just copying some or all input
+ * channels' data to output channels. Returns true and a table of input
+ * channel indices, or false otherwise.
+ *
+ * The table contains an entry for each output channels. Each table entry given
+ * either the input channel index to be copied, or -1 indicating that the
+ * output channel is not used and hence zero.
+ */
+bool pa_setup_remap_arrange(const pa_remap_t *m, int8_t arrange[PA_CHANNELS_MAX]);
+
#endif /* fooremapfoo */